Abstract: In a method and an apparatus for generating a portable sterilizing water that can be easily used at, for example, hospitals, cafeterias of nursing facilities, restaurants, hair salons or homes, an electrolyzer is structured such that a tubular-shaped ferrite anode and a cathode are arranged alternately in a concentric manner with an inter-electrode distance, and integrated with a pressurizable solution container containing halogen ions and a power control apparatus so that it can be carried and operated by one hand.

Abstract: A vacuum operated electrolytic generator can be used to produce a chlorine dioxide solution or a mist of chlorine dioxide from a buffered aqueous alkali metal chlorite solution in one pass through an electrolytic cell. The cell contains a high surface area anode, a corrosion-resistant highly conductive cathode, and a cation ion exchange membrane between the anode and cathode. An eductor is used on the anolyte effluent line to create a vacuum and draw the anolyte through the cell. Either motive water or a motive inert gas (such as air) is used in the eductor. Preferably, an eductor is used in the catholyte effluent line. An ascending anolyte effluent line with a non-corrosive check valve leads from the cell to the anode eductor. Sensors are used to monitor the composition of the anolyte effluent and/or the anolyte feed. The final product is a chlorine dioxide solution when water is used for the eduction.

Abstract: A method of producing chlorine dioxide gas in an enclosed space including the steps of electrochemically generating chlorine dioxide gas in an electrochemical cell and transporting the chlorine dioxide gas to the enclosed space.

Abstract: An electrolytic cell and process for the simultaneous production of hydrogen peroxide and hypochlorous ion. The electrolytic cell has an anode chamber housing an insoluble anode capable of oxidizing halide ion, a cathode chamber housing a gas diffusion cathode capable of oxidizing an oxygen-containing gas to produce hydrogen peroxide, a membrane separating the anode and cathode chambers, and means for supplying water containing halide ion to the anode chamber and an oxygen-containing gas and an electrolyte to the cathode chamber, whereby hypohalide and hydrogen peroxide are produced in the anode chamber and the cathode chamber, respectively. Also disclosed is a process for treating water using the electrolytic cell.

Abstract: An electrolytic cell for producing chlorine and basic hydrogen peroxide suitably includes an anode partition and a cathode partition separated by a membrane. The cathode partition is divided into a catholyte compartment and a gas plenum by a gas diffusion cathode. The anode partition electrolyzes alkali chloride received from the laser to produce free chlorine and alkali ions. The catholyte partition reduces oxygen received from the gas plenum through the cathode, and produces alkaline peroxide from the oxidized components combined with alkali ions received through the membrane from the anode partition. The cell is particularly useful in a fuel regeneration system (FRS) for a chemical oxygen iodine laser (COIL).

Abstract: The process and composition for to obtain chlorine dioxide in aqueous solution, ready to use, stabilized in buffer carbonate, being a powerful disinfectant agent, environmental classification, non residual, non toxic and non phytotoxic at use concentrations, characterized because the process understands an analysis of raw materials mainly the chloride metallic, main component for the reaction; it gets ready brines solution, the brine is a solution of sodium chloride at 20° C.-25° C. with soft water, the brine concentrations is at 9 to 15% parts in weight; then the brines are made go by an electrochemical cell, this cell are forming with silicoses iron, the composition is unknown, but is the same panels used in light conversion (DC/AC transformation) panels; the difference of potential is caused in voltaic cells at laminar regime, so that it produces the oxidation of the metallic chloride and to obtain in direct form the active principle of the invention, chlorine dioxide.

Abstract: Chlorine dioxide is produced at high conversion rates from aqueous sodium chlorite solution by electrochemical oxidation in an undivided electrochemical cell. The cell utilizes an anode of high surface area through which the aqueous sodium chlorite solution flows into an interelectrode gap between the anode and a cathode. Water or acidified water is fed into the interelectrode gap to function as catholyte and also to dilute the electrolyzed sodium chlorite solution to provide an aqueous solution of chlorine dioxide exiting from the electrochemical cell.

Abstract: A method of producing chlorine dioxide gas in an enclosed space including the steps of electrochemically generating chlorine dioxide gas in an electrochemical cell and transporting the chlorine dioxide gas to the enclosed space.

Abstract: There is provided waste treatment apparatus generally indicated as 10 and comprising a moulded plastic tank portion 11 forming an electrolysis chamber 13 and a holding chamber 14 separated by a bulkhead 15. The tanks are mutually closed at their tops by tank top 16 which closes over the bulkhead 15 to form substantially isolated spaces in the respective tanks. The electrolysis chamber 13 receives waste entrained in sea water from a macerating marine toilet (not shown) via a waste inlet 17 disposed at the upper portion of the electrolysis chamber 13. A displacement tube 20 picks up waste from the bottom of the electrolysis chamber 13 and discharges to the top of the holding chamber 14. A series of ruthenium/iridium oxide coated titanium electrode pairs 21 are disposed generally vertically to encourage vertical column circulation in the electrolysis chamber by virtue of the action of outgassed electrolysis products.

Abstract: Molecular fluorine may be generated and distributed on-site at a fabrication facility. A molecular fluorine generator may come in a variety of sizes to fit better the needs of the particular fabrication facility. The generator may service one process tool, a plurality of process tool along a process bay, the entire fabrication facility, or nearly any other configuration within the facility. The process can obviate the need and inherent risks with transporting or handling gas cylinders. The process can be used in conjunction with a cleaning or fabrication operation used in the electronics fabrication industry.

Abstract: An electrolytic process and apparatus for oxidizing inorganic or organic species is disclosed. The process and apparatus includes contacting a solution containing the inorganic or organic species with an electrocatalytic material disposed in an electrolytic reactor. Also disclosed are processes for fabricating a catalyst material for use in the electrolytic reactors and processes.

Abstract: In a method for producing sodium hypochlorite, brine solution is piped from the brine tank to a first inlet in a first electrolyzer cell of an electrolyzer assembly while simultaneously piping chilled water from a chiller having a temperature range from about 10° C. to about 25° C. to the first inlet so that the brine solution combines with the chilled water. The chilled brine solution is electrolyzed in the first electrolyzer cell. The hypochlorite and brine solution resulting from electrolysis occurring in the first cell is piped to a second inlet in a second electrolyzer cell in the electrolyzer assembly while simultaneously piping chilled water from the chiller having a temperature range from about 10° C. to about 25° C. to the second inlet so that the chilled water combines with the hypochlorite and brine solution. Each cell can have more than one inlet, preferably up to 6 inlets. The chilled hypochlorite and brine solution are electrolyzed in the second cell.

Abstract: The invention is directed to compositions of health and beauty care products which are produced by mimicking the human body's own defense mechanisms and the methods to produce and use such compositions. The products are water based, oil and surfactant free and can be antimicrobicidal, without causing drying or itching of the skin. Moreover, such products enhance hydration and moisturizing of the skin and prevent itching. The products are based on water solutions of mixed oxidants, mimicking those produced by the human immune system cells. The invention also describes the processes for producing such products. Such products can be used independently, or to prepare creams, gels, lotions, tooth and other pastes, powders, suppositories, body and hair shampoos and rinses, oral and body hygiene rinses, creams and other products which would be obvious to those skilled in the art.

Abstract: In a method and an apparatus for generating a portable sterilizing water that can be easily used at, for example, hospitals, cafeterias of nursing facilities, restaurants, hair salons or homes, an electrolyzer is structured such that a tubular-shaped ferrite anode and a cathode are arranged alternately in a concentric manner with an inter-electrode distance, and integrated with a pressurizable solution container containing halogen ions and a power control apparatus so that it can be carried and operated by one hand.

Abstract: A continuous use chemical oxygen iodine laser requires a continuous supply of basic hydrogen peroxide and chlorine to produce singlet delta oxygen for the laser. Regeneration of the spent basic hydrogen peroxide and chlorine with the input of oxygen and electricity can be generated on site or be obtained from a power grid. The regeneration of the spent basic hydrogen peroxide and chlorine makes continuous use of a chemical oxygen iodine laser possible without the constant resupply of basic hydrogen peroxide from an outside source.

Abstract: Chlorine dioxide is produced at high conversion rates from aqueous sodium chlorite solution by electrochemical oxidation in an undivided electrochemical cell. The cell utilizes an anode of high surface area through which the aqueous sodium chlorite solution flows into an interelectrode gap between the anode and a cathode. Water or acidified water is fed into the interelectrode gap to function as catholyte and also to dilute the electrolyzed sodium chlorite solution to provide an aqueous solution of chlorine dioxide exiting from the electrochemical cell.

Abstract: An electrode having an electrocatalytic surface or coating composed of a mixture with iridium oxide is used in a reversible polarity electrolytic cell to selectively produce an alkali metal hypohalite, preferably sodium hypochlorite, from brine made from hard water. The mixture also may have a platinum group metal oxide and a valve metal oxide, preferably, ruthenium oxide and titanium oxide respectively.

Abstract: An electrode for electrolyzing an electrolyte comprising an ammonium fluoride (NH4F)-hydrogen fluoride (HF)-containing molten salt and having a composition ratio (HF/NH4F) of 1 to 3 to prepare a nitrogen trifluoride (NF3) gas and an electrolyte for use in the preparation of NF3 gas, and a preparation method of the NF3 gas by the use of the electrode and the electrolyte. The electrode comprises nickel having 0.07 wt % or less of Si content and containing a transition metal other than nickel. The electrolyte also contains a transition metal other than nickel.

Abstract: An apparatus and method for venting hydrogen from an electrolytic cell. A brine solution is supplied to an electrolytic cell where hypochlorite and hydrogen gas are produced. A non-combustible gas is introduced into the electrolyzer containing the electrolytic cell and the concentration of hydrogen in the electrolyzer is reduced to a concentration below the LEL of hydrogen.

Abstract: A production apparatus of hypochlorite solution includes an electrolytic cell having a housing the interior of which is subdivided by a partition membrane to form therein anode and cathode chambers, and positive and negative electrodes respectively disposed within the anode and cathode chambers and opposed to each other through the partition membrane, wherein the positive and negative electrodes are applied with DC voltage to effect electrolysis of chloride solution such as sodium chloride solution or potassium chloride solution supplied into both the anode and cathode chambers, and wherein acid water and alkaline water respectively produced in the anode and cathode chambers are mixed to produce hypochlorite solution.

Abstract: The invention relates to a process for production of an alkaline hydrogen peroxide solution and an acidified alkali metal salt solution containing chlorate in an electrochemical cell including an anode compartment provided with an anode and a cathode compartment provided with an oxygen reducing cathode. In the cathode compartment an aqueous alkali metal hydroxide and hydrogen peroxide is formed, wherein the molar ratio MOH:H2O2 for the net production thereof is maintained from about 0.1:1 to about 2:1. Also a process for simultaneous production of chlorine dioxide is disclosed.

Abstract: Chlorine dioxide dissolved in water is produced by passing a solution of stabilized chlorine dioxide or sodium chlorite solution, with or without added sodium chloride, through an electrolytic cell having an anode and cathode, in the absence of a semi-permeable membrane but in the presence of a buffer, an anolyte with a pH below 10 is produced so that disproportination of the ClO2 is not appreciable.

Abstract: Method of controlling biofouling and microorganism population levels in a water system, comprising adding to the water a redox buffer and oxidizing thereafter. The redox buffer may be a peroxide or hydrogen peroxide (H2O2), which is added to the water. The redox buffer keeps the redox potential between about 250 to 450 mV. The oxidant may include a halogenating chemical which is chosen from among the hypohalite species, such as HOCl, NaOCl, NaOBr, HOBr, OBr−, OCl−, Br2, Cl2 and acid solutions. The acid solution is selected from among those containing (Cl2+HCl), (Br2+HBr), (Br2+HCl), trichlorocyanoric acid (TCCA), bromochlorodimethyl hydantoin (BCDMH), dibromodimethyl hydantoin (DBDMH), dichlorodimethyl hydantoin (DCDMH), and other halogen agents, preferably an active chlorine donor or sodium hypochlorite (NaOCl) or hypohalide acid (HOX), such as hypochlorous acid (HOCl) or hypobromous acid (HOBr), or hypohalite ion OX, wherein X is Cl or Br, or halohydantoin.

Abstract: A process for converting in a single pass an aqueous alkaline pH, alkali metal chlorite solution into an aqueous chlorine dioxide-containing solution that involves the combination of (1) using an electrochemical acidification cell to lower the pH value of the aqueous alkali metal chlorite feed before it enters the anode compartment of an electrochemical oxidation cell where the chlorite is converted to chlorine dioxide with (2) using an anolyte flow pattern where the anolyte passes through a porous, high surface area electrode. This process results in a substantially improved conversion efficiency per pass.

Abstract: The present invention provides a process for generating an aqueous solution containing at least one active bromine compound comprising the steps of: electrolyzing an aqueous solution containing bromide ions until bromate ions are formed in said aqueous solution; and introducing to the aqueous solution containing bromate ions an acid to generate an aqueous solution containing at least one active bromine compound. The present invention also provides an apparatus for generating an aqueous solution containing at least one active bromine compound. The aqueous solution containing the active bromine compound(s) generated using the process and apparatus of the present invention may be used for water treatment and the recovery of precious metals such as gold.

Abstract: A bipolar metal electrode for the electrolysis of hydrochloric acid, comprising a nickel alloy cathode plate and a titanium anode mesh coupled together by a hydrogen barrier, where the hydrogen barrier is an aluminum plate, where the titanium anode mesh is connected to a titanium backplate by a plurality of titanium supports and where the titanium backplate is spaced apart from the nickel alloy cathode plate by the aluminum plate. An electrolyser comprising one or more bipolar electrodes according to present invention. A method of producing chlorine from hydrochloric acid comprising providing one or more bipolar metal electrodes according to the present invention or an electrolyser according to the present invention, and contacting the one or more bipolar electrodes or the electrolyser with hydrochloric acid.

Abstract: In removal of sulfate groups and chlorate groups from brine used for electrolysis, concentrated brine used in an electrolysis process or dilute brine whose concentration is decreased by electrolysis is fed to an anode chamber divided by a cation exchange membrane in a brine treating electrolyzer, where the concentrated or dilute brine is electrolyzed to recover chloride ions therein. The concentrated brine is electrolyzed at a rate of decomposition of salt higher than that in the ion exchange membrane electrolysis process of brine. Thereafter, the concentrated or dilute brine is discharged out of the electrolysis process.

Abstract: A recirculation system for electrochemically activated antimicrobial solutions returns antimicrobial solution which has been depleted of active antimicrobial species to a electrolytic cell for regeneration of the active species. Organic load, which frequently contaminates items to be sterilized or disinfected, such as medical instruments, rapidly depletes the active antimicrobial species in a conventional treatment system, reducing the effectiveness of microbial decontamination by electrochemically activated solutions. By recirculating the antimicrobial through the electrolytic cell, the concentration of active species is maintained at a level at which efficient sterilization is achieved.

Abstract: The present invention discloses a method of producing hydrogen halide and oxygen by reacting water and halogen as represented by the following formula:H.sub.2 O+X.sub.2 .fwdarw.HX+1/2O.sub.2 ( 1)(wherein, X represents a halogen), wherein activated carbon is used as catalyst, said activated carbon is inserted into an aqueous solution containing said halogen as an electrode, a counter electrode is inserted into said solution and, after bringing this counter electrode into contact with said active carbon electrode, the above reaction takes place in a reaction system in which said activated carbon electrode and counter electrode are connected outside said aqueous solution. Moreover, a voltage is applied between the activated carbon electrode and counter electrode, and contact between the activated carbon electrode and counter electrode is made through an anion electrolyte membrane. In addition, openings are provided in this anion electrolyte membrane.

Abstract: Operating efficiency of an electrobromination device providing disinfectant to an aqueous medium such as a swimming pool, spa, or water-cooled refrigeration unit is achieved by passing electric current across an undivided cell through which is flowing an aqueous medium containing bromide ions and a nitrogen-containing electrobromination-enhancing adjuvant such that bromide ions are electrolytically oxidized to bromine in the aqueous medium under conditions enabling formation in situ of hypobromous acid, dissociated hypobromous acid, or both.

Abstract: Chlorine dioxide is generated by electrochemical oxidation of sodium chlorite in an anode compartment of a cation-exchange membrane-divided cell in the presence of significant quantities of sodium chlorate and is recovered in a suitable recipient medium by passing the chlorine dioxide through a hydrophobic microporous membrane. Water balance in a continuous operation is maintained by removing water from the anolyte by transporting the same partly across the hydrophobic microporous membrane in vapor form and partly across the cation-exchange membrane.

Abstract: A method of electrolytically producing acid water using an electrolytic cell partitioned by a cation-exchange membrane into an anode chamber and a cathode chamber. Chloride ion which generates hypochlorous acid by anodic oxidation is supplied to the cathode chamber without directly supplying chloride ion to the anode chamber. Part of the chloride ion permeates from the cathode chamber into the anode chamber through the cation-exchange membrane. The chloride ion which permeates through the cation-exchange membrane is present at the surface of an anode closely adhering to the cation-exchange membrane in the anode chamber or only in the vicinity of the anode, and is efficiently anodically oxidized to form hypochlorite ion. Also disclosed is an electrolytic cell for carrying out the method of electrolytically producing acid water.

Abstract: An electrochemical cell (1 ) having a proton-conducting membrane (4) is used in the process for the direct electrochemical gas phase synthesis of phosgene. Dry HCl gas and dry CO gas are supplied as the educts to the anode (2) of the electrochemical cell (1). The chlorine radicals formed on anodic oxidation of the HCl gas then react directly with the CO gas to yield phosgene, while the simultaneously formed protons migrate through the membrane (4) to the cathode (3) and are there reduced to hydrogen or, in the presence of oxygen, to water.

Abstract: Chlorine dioxide is generated by electrochemical oxidation of sodium chlorite in an anode compartment of a cation-exchange membrane-divided cell and is recovered in a suitable recipient medium by passing the chlorine dioxide through a hydrophobic microporous membrane. Water balance in a continuous operation is maintained by removing water from the anolyte by transporting the same partly across the hydrophobic microporous membrane in vapor form and partly across the cation-exchange membrane.

Abstract: A strong acid sterilizing liquid containing hypochlorous acid at a low concentration consists of electrolyzed salt water, wherein the pH of the liquid is 3 or less and the concentration of the hypochlorous acid is 0.2 ppm to 2 ppm.

Abstract: Chlorine dioxide is produced by reaction of chlorate ions, usually provided by sodium chlorate, with a persulfate in an aqueous acid reaction medium containing sulfuric acid. By-product sodium sulfate, sulfuric acid feedstock or mixture may be electrolyzed to form the persulfate for the reaction.

Abstract: The present invention provides a process for generating an aqueous solution containing at least one active bromine compound comprising the steps of: electrolyzing an aqueous solution containing bromide ions so that bromate ions are formed in said aqueous solution; and introducing to the aqueous solution containing bromate ions an acid to generate an aqueous solution containing at least one active bromine compound. The present invention also provides an apparatus for generating an aqueous solution containing at least one active bromine compound. The aqueous solution containing the active bromine compound(s) generated using the process and apparatus of the present invention may be used for water treatment and the recovery of precious metals such as gold.

Abstract: A process for the production of chlorine dioxide by reacting at least one of chloric acid and an alkali metal chlorate, and hydrogen peroxide as the reducing agent in such proportions that chlorine dioxide is produced in a reaction medium. A mixture comprising chlorine dioxide and oxygen is withdrawn from the reaction medium. Urea and/or one or more phosphonic acid based complexing agents are added to the reaction medium. The stabilizer is added in an amount of 0.01-5 weight % and serves to increase the reaction rate.

Abstract: Disclosed is a process of producing chlorine dioxide having the steps of providing a reactor with an aqueous acidic reaction medium containing alkali metal chlorate and phosphate; reducing chlorate ions in the reaction medium to form chlorine dioxide; withdrawing chlorine dioxide gas from the reaction medium; withdrawing reaction medium from the reactor and transferring it to an electrochemical cell; treating the reaction medium electrochemically to increase the acidity and decrease the content of alkali metal ions; recycling the acidified reaction medium to the reactor; and adding make up alkali metal chlorate to the reaction medium before or after the electrochemical cell.