Embodiments of the present disclosure relate generally to systems and methods for combing ozone and water to deliver ozonated water in a rinse stream. The ozone rain pan finds particular use for rinsing food products traveling along a conveyor line with ozonated water.

Technologies (e.g., devices, systems and methods) for sanitizing hot beverage makers are described. In some embodiments, the technologies include a sanitization gas system that is configured to be install into a cover, onto a wall or cover and between a the top rim of the reservoir and the cover of the reservoir. The sanitization gas system may provide a sanitizing gas to the reservoir for sanitizing the reservoir, sidewalls, bottom tray and cover.

Technologies for providing a gas inlet and gas outlet to a compartment are described. In embodiments, the technologies include a dual channel connector unit that includes an inlet passageway and an outlet passageway. In embodiments at least a portion of the outlet passageway is disposed radially around the inlet passageway. The connector unit is configured to install into a portion (e.g., wall, bottom, top, or lid) of a compartment. Systems and methods including such connector units are also described.

Technologies (e.g., devices, systems and methods) for sanitizing reservoirs are described. In some embodiments, the technologies include a sanitization gas system and a connector unit. The connector unit is configured to install into a portion (e.g., wall, bottom, top, or lid) of a reservoir, such as a reservoir of a hot beverage maker. The connector unit includes an inlet passageway for supplying sanitizing gas (e.g., ozone) into the reservoir, and an outlet passageway for removing sanitizing gas from the reservoir. In some embodiments at least a portion of the outlet passageway is disposed radially around the inlet passageway. The sanitization gas system may provide a sanitizing gas to the inlet passageway and receive the sanitizing gas from the outlet passageway.

The blow molding device (1) is provided with a heating means (4) for heating a preform (P) to a temperature appropriate for molding, an antimicrobial agent-spraying means (50) for spraying an antimicrobial agent on the preform (P), a hot forming means for stretch blow molding the preform into a bottle (B), and an irradiation device (7) irradiating electromagnetic waves or ultrasonic waves on the bottle. After the heating means (4) has heated the preform (P), the anti-microbial agent-spraying means (50) sprays the anti-microbial agent and sterilizes the preform (P) with hot antimicrobial agent. During subsequent stretch blow molding of the preform (P), the hot forming means performs additional drying of antimicrobial agent retained on the preform (P) in the hot state and additional sterilization. The irradiation device (7) irradiates electromagnetic waves or ultrasonic waves to degrade the anti-microbial agent remaining on the molded bottle (B) and further promote antimicrobial agent drying and sterilization.

A cap assembly for attachment to an equalization port on an endoscope, comprising a tubular housing defining an internal chamber, a mounting section releasably attached to the housing in fluid-tight fashion and attachable to the equalization port of an endoscope, wherein the internal chamber communicates with the equalization port; a barrier layer formed of a reactive material disposed within the internal chamber, a first cavity defined between the barrier layer and a first end of the housing; a second cavity defined between the barrier layer and the mounting section, the second cavity dimensioned to receive an indicator test strip that is capable of detecting a gaseous germicide; and a filter layer disposed between the barrier layer and the first end of the housing.

A sterilization system including an oxygen generator, an ozone generator, a mixer, a wash chamber, and a sterilization chamber is disclosed. The oxygen generator is configured to generate a flow of oxygen. The ozone generator is in fluid communication with the oxygen generator, and configured to generate a flow of ozone from the flow of oxygen. The mixer is in fluid communication with the ozone generator and configured to receive the flow of ozone and a flow of cleaning fluid, and mix the flow of ozone into the flow of cleaning fluid, resulting in a flow of ozonated cleaning fluid. The wash chamber is in fluid communication with the mixer and configured to receive the flow of ozonated cleaning fluid from the mixer. The sterilization chamber is in fluid communication with the ozone generator and is configure to receive the flow of ozone.

A pre-conditioned air (PCA-) device is provided for conditioning air in an interior of a cabin of a parked aircraft (12) and for sanitizing an air and surfaces in the interior of the cabin. The PCA-device includes an air pre-conditioning (PCA-) unit (1) for forming a stream of pre-conditioned air (5c); a photo catalytic oxidation unit (2) for forming reactive oxygen species (ROS) in the stream of pre-conditioned air including dry hydrogen peroxide at a concentration below 1 ppm, thus forming a stream of peroxided air (5p); and an air distribution ducting (3) for injecting the peroxided air (5p) into an internal air circulation duct of an aircraft, wherein the photo catalytic oxidation unit (2) includes a source of ultraviolet (UV-) light (2uv) configured for irradiating a UV-volume with UV-light; and a catalyst (2c) located within the UV-volume and intersecting the stream of pre-conditioned air.

Provided is a method for decomposing peracetic acid and a method for culturing microorganisms using the decomposition method. The cultivation of microorganisms using the method of the present invention allows an effective removal of the peracetic acid used in a culture medium for sterilization.

A continuous decontamination-and-sterilization device possessing high efficiency, reliability, and safety of operation to treat external surfaces of a package that is conveyed to a sterile working chamber. A decontamination chamber decontaminates (with a decontamination agent) bottom and lateral external surfaces of the package conveyed by a first conveyance, with an upper surface seal portion of the package being sealed. An aeration chamber removes residue of decontamination agent from an external surface of the package while the package is conveyed by a second conveyance means. A sterilization chamber sterilizes the upper surface seal portion of the package by irradiating electron beams as the package is conveyed by a third conveyance means, with the bottom or lateral external surface of the package being supported. The first conveyance means includes a sealing means by an adsorbing function to adsorb and capture the upper surface seal portion so as to seal the same and convey the package, with the bottom and lateral external surface portions of the package being open.