Methods for true sterilization of an object, methods for inactivating an infectious protein, and methods for inactivating a microbial pathogen using a bufferless, electrolyzed, hypohalous acid composition.

According to an embodiment, there is provided herein a method of using electrolyzed oxidizing water ice (EO ice) as a Cleaning-In-Place (CIP) method that reduces antimicrobial contamination. One embodiment is utilized in connection with beef grinders. In one embodiment, EO ice was prepared by freezing 200 mg/L free chlorine-containing EO water at 20° C. overnight. The EO ice and, optionally, EO ice/water mixture was then ground within an operating meat grinder. The EO ice treatment in combination with EO water has the potential to reduce cross-contamination and could serve as an easy to apply antimicrobial intervention to improve overall safety of ground beef.

Methods and systems for sanitization of liquid solutions and food products are provided. In some embodiments, methods are provided for treating a food product or food product preparation or packaging surface to reduce microbial content, comprising contacting the food product or food product preparation or packaging surface with a chlorinated nanobubble solution comprising electrolyzed water. In some embodiments, methods are provided for reducing the growth of bacteria and reversing the growth of biofilm in a water system, comprising chlorinating source water and passing the chlorinated source water through a low zeta potential crystal generator. In some embodiments, methods are provided for purifying water, comprising chlorinating the water and passing the chlorinated water through a low zeta potential crystal generator.

The present invention discloses an integrated technique for sterilization or disinfection or sanitization, to remove microbial load in air or in liquid or on solid surfaces using water, gases and electrical energy. Electrical energy is used in the present invention to generate ions or electrically activated species from mixture of gases generated from electrolysis, air and water mist which can be directly used for sterilization or can be dissolved in water to create electrically activated water. This water is directly used for surface disinfection or may be converted into activated water mist for disinfection of air. The gas plasma or activated water mist may also be dissolved in water for disinfection of water.

According to the embodiment, a sanitary washing device includes a private part washing nozzle, a casing, a sterilizing water generator, and an illuminator. The private part washing nozzle discharges water toward a private part of a user in a state of the private part washing nozzle is advanced into a toilet. The casing includes a nozzle storage part configured to store an entirety of the private part washing nozzle in a state of the private part washing nozzle is retracted. The sterilizing water generator generates sterilizing water supplied to the private part washing nozzle and the nozzle storage part. The illuminator irradiates sterilizing light into the nozzle storage part. The sterilizing light has a sterilizing action. The illuminator irradiates the sterilizing light toward a residual water occurrence portion at which the sterilizing water supplied into the nozzle storage part remains.

According to the embodiment, a sanitary washing device includes a nozzle, a casing, an illuminator, and a controller. The nozzle discharges water toward a private part of a user in a state of the nozzle is advanced into a toilet. The casing includes a nozzle storage part configured to store an entirety of the nozzle in a state of the nozzle is retracted. The illuminator irradiates sterilizing light into the nozzle storage part. The sterilizing light has a sterilizing action. The controller controls the illuminator. The controller includes a first irradiation mode of causing sterilizing light irradiated from the illuminator to be irradiated toward an outer circumferential surface of the nozzle. The controller includes a second irradiation mode of causing sterilizing light irradiated from the same illuminator as the first irradiation mode to be irradiated toward an inner wall of the nozzle storage part.

A disinfection system device for producing ozone water directly in a water pipe system contains an electrolytic tap water ozonation generator and holder. The electrolytic tap water ozonation generator includes at least one anode sheet and at least one cathode sheet. The holder includes a base, and the base has a locking portion, an inflow orifice, an outflow orifice, a connection interface, and a damping valve. A flow switch is mounted above the base and has an intake, and a discharge orifice of the flow switch is communicated with the outflow orifice. A top of the base is connected with one of two lids, the other lid is connected with the first socket and a second socket, and the other lid accommodates a control panel. The number of the anode sheet(s) is n which is a natural number and n≥1. The number of the cathode sheets is n+1.

The present disclosure relates generally to an electrolyzed water generator, kit and method of use. More particularly, the present disclosure relates an electrolyzed water generator with a producing bottle and a solution bottle. Specifically, the present disclosure a method and apparatus of generating electrolyzed water using an apparatus that is able to accurately dose water in a residential or business setting without further devices.

An apparatus that can be connected to a conventional sprayer bottle that permits the sprayer bottle to generate ozonated water to be used as a cleaning fluid. The apparatus includes an insert member that can be releasably inserted between the spray head and the bottle portion. An ozonator element is coupled to the insert member via an electrical cable and wherein the ozonator element is configured to be submerged within a liquid contained within the bottle portion. With the insert secured on the bottle portion, the dip tube of the spray head can be passed through the insert member and into the liquid in the bottle portion and the spray head is secured onto the insert member. Electrical energy is provided through insert member to the ozonator element to ozonate the liquid in the bottle for predetermined period of time after which the sprayer bottle contains an ozonated liquid for cleaning. After another predetermined period of time, the ozonator element is energized again to ensure ozonated liquid is always available.

The present invention relates to an electrochemical device for releasing ions, comprising an electrical circuit comprising a first electrode and a second electrode adapted for providing a galvanic cell when the electrodes are exposed to a fluid constituting an electrolyte, and a boost converter adapted for amplifying a potential generated between the first and the second electrode. The electrical circuit further comprises a third electrode connected with an output side of the boost converter, wherein the second and the third electrode constitutes an electrolytic cell powered by the galvanic cell when the electrodes are exposed to a fluid. The present invention further relates to devices, such as a toothbrush or a shaver, adapted for being used in connection with a fluid, comprising such electrochemical device for releasing ions.