A method for sterilizing closure elements (3) for packaging containers (1), wherein the closure elements (3) are collected individually by a holding mechanism (25) in the region of a sterile chamber (12) and are placed onto an opening (4) of a filled packaging container (1) and connected to the latter, and wherein the closure elements (3), while being conveyed inside the sterile chamber (12), are treated by means of at least one sterilizing medium (6, 7, 52) during a sterilizing process.

A wearable system for dispensing a substance is disclosed. The wearable system includes a base element, at least one reservoir surface defining a reservoir disposed in the base element, at least one first opening disposed along on an outward facing portion of the base element and providing fluid communication with the reservoir, and a rolling element disposed in the at least one first opening such that a first portion of the rolling element is outside the base element and a second portion of the rolling element is inside the base element.

A personal, portable, handheld UV light sanitizer (20) having a tubular housing (22) with a UV light source (32) for uniformly radiating a user's hand through a light transmittable outer wall (24) of the housing having a girth and length that enables substantially the entire the exterior surface of the outer wall to be covered by a user's hand when fully grasping the outer wall. A rearward annular wall (41) reduces any rearward light leakage and provides a bearing surface against which the edge of the user's hand may rest to prevent slippage. An annular forward wall (40) reduce forward light leakage and mounts actuation switches (36, 56), remote sensors (58, 60), a status indicator light (61) and an alarm speaker (59). When the skin surface sanitization mode switch (36) is actuated, skin sanitizing UV light radiation (42) radiates the inside of the user's hand for a preselected time period, unless there have previously been an excessive number of past hand sanitization cycles or too little time has passed since the last hand sanitization cycle (FIG. 9). Once energization, it is automatically deenergized after a preselected maximum time period (FIG. 9). Mounted to the front of the forward annular wall is another UV light source (51) that radiates UV light to suspect target surfaces spaced from the user's hand. A range finder (58) helps the user to hold the surface UV light source at the right distance from the target surface for effective sanitization, and energization is immediately terminated in response to an infrared sensor detecting that the surface UV light source is directed at a person's skin.

A decontamination rack is particularly suitable for decontaminating medical devices, such as endoscopes, for being designed to minimize shadowed surface area. The decontamination rack may be provided with internal channels through which a decontamination fluid may be supplied to the locations where a device contacts decontamination rack. These locations may comprise receiving areas having ejection ports with flexible nozzles disposed therein. The device may be disposed atop the nozzles such that the decontamination fluid exits the nozzles to impinge directly on those portions of the device that rest upon the nozzles. The use of the decontamination rack promotes improved or complete coverage of exposed external surfaces of the device with the decontamination fluid because decontamination fluid may be ejected into the receiving area to lift the device at the shadowed surface.

A system for meat processing may include: a conveyor configured to transport animal carcasses or portions of meat through a meat processing facility; and a spray system configured to spray each of the animal carcasses or portions of meat with aqueous ozone when each of the animal carcasses or portions of meat is transported to the spray system by the conveyor. The system may further include a second spray system configured to spray each of the animal carcasses or portions of meat with lactic acid or citric acid when each of the animal carcasses or portions of meat is transported to the second spray system by the conveyor.

An indoor gardening appliance includes a grow module positioned within a grow chamber for receiving one or more plant pods. The indoor gardening system includes a hydration and sanitization system that includes a water supply for providing a flow of water into a mixing tank that is periodically discharged through a discharge nozzle to hydrate and provide nutrients to plants. A sanitization assembly includes an electrolytic hypochlorous acid generator that is fluidly coupled to the mixing tank for selectively generating hypochlorous acid that helps sanitize plants within the grow chamber.

Described herein is a method of forming individual tubes or sachets containing fluent material, and a packaging machine for doing so, are described. The side of the foil which will be in contact with the fluent material when the package is formed is exposed to plasma in mist or aerosol form as the tube or sachet is formed from a strip of laminate material (1), which is folded about a former (2) into a closed tube or sachet which passes over the open end of a dispensing tube (3) from which the fluent material is dispensed. A mist of plasma is injected into the interior of the material tube as it is formed, extracted from the area once it has passed over the interior walls of the laminate tube.

The present invention achieves a decontamination effect with a proper amount of hydrogen peroxide mist supplied to a room to be decontaminated by further refining such hydrogen peroxide mist supplied to the room for dispersion/diffusion, and reducing the duration of operations such as aeration to increase efficiency of decontamination.

The decontamination system includes a mist generation means, a mist discharge port, and a mist dispersion/diffusion means. The mist generation means converts a decontamination liquid into a mist to generate a mist for decontamination. The mist discharge port is opened at an upper portion on an internal side wall surface of the room to discharge a such mist into the inside of the room. The mist dispersion/diffusion means generates sound flows by an ultrasound in the vertical direction from a plate surface of a vibration plate provided adjacent to a lower portion of the mist discharge port on the internal side wall surface of the room or adjacent to a lower portion on a side surface in a mist discharge direction. The mist is pressed by acoustic radiation pressure backward or laterally in intermittent operation or stronger/weaker operation of the system.

A hand-held operation cleaning, sterilization and disinfection atomizing diffuser, provided that the user conveniently holds a handle of the diffuser to operate a control unit to provide power to an air extraction device and a pumping control device to pump the cleaning, sterilizing, disinfecting or/and deodorizing liquid out of a liquid storage tank to expel via a water jet, and the gas extracted from the air extraction forms a jet stream through an air jet, and the liquid sprayed by the water jet is broken by the jet stream of the air jet at a high speed into fine droplets and atomized to clean, sterilize, disinfect or deodorize towards a target.

A disposable cleaning unit is described herein including an inner receptacle and an outer receptacle.