A hair perm forming method using electrolyzed water multiple times or for a predetermined period of time or more was revealed to have effects that cause very little damage to the hair to enable repeated treatments, enable perming of damaged hair and blonde hair compared with existing methods, show oxidative power higher than that of hydrogen peroxide, cause less hair damage, suppress dandruff bacteria, and significantly decrease the elution of dyes after perming. Therefore, the hair perm forming method can be advantageously used to effectively form a perm without harm to the human body. In addition, the washing of dyed and permed hair, dyed hair, and bleached hair with electrolyzed water, compared with washing with distilled water, has advantages in that the tensile strength of hair is maintained and the dye loss from the dyed hair is less.

A hair perm forming method using electrolyzed water multiple times or for a predetermined period of time or more was revealed to have effects that cause very little damage to the hair to enable repeated treatments, enable perming of damaged hair and blonde hair compared with existing methods, show oxidative power higher than that of hydrogen peroxide, cause less hair damage, suppress dandruff bacteria, and significantly decrease the elution of dyes after perming. Therefore, the hair perm forming method can be advantageously used to effectively form a perm without harm to the human body. In addition, the washing of dyed and permed hair, dyed hair, and bleached hair with electrolyzed water, compared with washing with distilled water, has advantages in that the tensile strength of hair is maintained and the dye loss from the dyed hair is less.

The present invention relates to a hybrid system for water treatment, desalination, and chemical production. The hybrid system of the present invention includes a photoanode, an anode chamber, an anion exchange membrane, a middle chamber, a cation exchange membrane, a cathode chamber, and a cathode. In the middle chamber, saltwater or seawater is desalinated by photoelectrochemical electrodialysis. Chloride ions are generated during the desalination, transferred to the anode chamber, and activated by the photoanode. In the anode chamber, wastewater is treated by the activated chloride ions. In the cathode chamber, at least one chemical species selected from the group consisting of water, oxygen, and carbon dioxide is reduced by electrons supplied from the photoanode.

A method for mitigating formation of biofilm in a water system using predictive analysis of biofilm growth. An electrical current to the water system is used to deactivate bacteria and mitigate biofilm formation. The method also allows for optional dosing of the water system with biocide. A system is also used for mitigating formation of biofilm in a water system, made of a bacterial deactivator, a biofouling sensor, a biofouling potential analyzer, and a controller to synthesize data from the analyzer and sensor to model and predict biofouling events and operate the bacterial deactivator based upon the modeling and prediction.

A method for mitigating formation of biofilm in a water system using predictive analysis of biofilm growth. An electrical current to the water system is used to deactivate bacteria and mitigate biofilm formation. The method also allows for optional dosing of the water system with biocide. A system is also used for mitigating formation of biofilm in a water system, made of a bacterial deactivator, a biofouling sensor, a biofouling potential analyzer, and a controller to synthesize data from the analyzer and sensor to model and predict biofouling events and operate the bacterial deactivator based upon the modeling and prediction.

The wastewater treatment apparatus of present invention has an electro-coagulation unit for removing contaminants with at least one anode and at least one cathode and an electro-oxidation unit for oxidizing contaminants with at least one anode and at least one cathode wherein oxidants are electrochemically generated. Based on the type of wastewater, the apparatus can have an electro-flotation unit between the electrocoagulation unit and the electro-oxidation unit. The apparatus also has an oxidant removal unit which can have a metal ion-liberating electrode for reacting with and removing residual oxidants. In some cases, portions of effluent from the oxidant removal unit can be recirculated to the electro-coagulation unit for increased efficiency.

A method and apparatus for removing specific contaminants from an aqueous solution in a recirculating tank or linear treatment system is described. An aqueous solution is pumped into a reaction chamber. Measurements from the aqueous solution are collected, including one or more of Free Chlorine, Total Chlorine, Total Ammonia Nitrogen, pH, bacteria in the tank, and Oxidation Reduction Potential. In response to the measurements collected, one or more of pump speed, injection of pH precursors prior to the reaction chamber, reaction chamber electrode voltage, current, infusion rate of the chlorine, and contact time of the aqueous solution with the chlorine, are adjusted.

A sterilized water generator to control some of a plurality of electrolysis modules not to perform electrolysis on water brought into the sterilized water generator. The sterilized water generator includes a water inlet pipe through which water flows in; a water outlet pipe through which sterilized water flows out; a plurality of electrolysis modules arranged in parallel between the water inlet pipe and the water outlet pipe and configured to turn the water brought in through the water inlet pipe to the sterilized water; and a controller configured to control a forward voltage not to be applied to a first electrolysis module of the plurality of electrolysis modules, control the forward voltage to be applied to a second electrolysis module of the plurality of electrolysis modules, and change electrolysis modules corresponding to the first and second electrolysis modules of the plurality of electrolysis modules based on a lapse of time.

A sterilized water generator to control some of a plurality of electrolysis modules not to perform electrolysis on water brought into the sterilized water generator. The sterilized water generator includes a water inlet pipe through which water flows in; a water outlet pipe through which sterilized water flows out; a plurality of electrolysis modules arranged in parallel between the water inlet pipe and the water outlet pipe and configured to turn the water brought in through the water inlet pipe to the sterilized water; and a controller configured to control a forward voltage not to be applied to a first electrolysis module of the plurality of electrolysis modules, control the forward voltage to be applied to a second electrolysis module of the plurality of electrolysis modules, and change electrolysis modules corresponding to the first and second electrolysis modules of the plurality of electrolysis modules based on a lapse of time.

Provided, according to one aspect of the present invention, are a sodium hypochlorite production system and a water treatment method using same, the sodium hypochlorite production system comprising: a first means for obtaining saturated brine and purified water using a first sub-stream branching off from a main stream of water to be treated; a second means for obtaining an anodic product and cathodic product by electrolyzing the saturated brine and purified water; and a third means for obtaining sodium hypochlorite by reacting the anodic product and cathodic product using a second sub-stream branching off from the main stream of the water to be treated.