A locker includes a pair of upstanding sidewalls, upper and lower horizontal panels, a plenum, and at least one compartment defined between the upstanding sidewalls. A chemical dispensing unit is disposed on or in the locker relative to the upper and lower horizontal panels, over and/or between the sidewalls. A first fan is disposed between the chemical dispensing unit and the plenum of the locker. The first fan pulls air and chemical into perforations formed in the locker to dispense the chemical throughout and in close proximity to the locker and remove dirty air. The first fan, or a second fan, draws clean air through the perforations of the locker. The dirty, chemical-integrated-air exits the locker room out an exhaust vent and is replaced by the clean air.

A disinfection system including an enclosed chamber and a source of a disinfecting vapor connected to the enclosed chamber, wherein the disinfecting vapor includes nitric acid. Methods of disinfecting a contaminated article are also described, the methods including placing the contaminated article within an enclosed chamber of a disinfection system and exposing the contaminated article within the enclosed chamber to a source of a disinfecting vapor including nitric acid for an exposure time sufficient to disinfect the contaminated article by achieving a reduction in colony forming units of the disinfected contaminated article relative to the contaminated article. Exposing the contaminated article within the enclosed chamber to the source of the disinfecting vapor may include alternately exposing the contaminated article to the disinfecting vapor for a first time interval, and exposing the contaminated article to a water vapor for a second time interval.

A decontamination device (1) for decontaminating products in the form of consumer goods and/or consumer good packaging having consumer goods located therein prior to supplying the consumer goods into an isolator, the decontamination device comprising several decontamination chambers (3, 4, 5, 6) each having a closable inlet opening (9) and a closable outlet opening (10), and each comprising application means (7) for applying a decontamination agent, to the decontamination chambers (3, 4, 5, 6), and the decontamination device (1) comprising a distributor chamber (11) disposed upstream of the decontamination chambers (3, 4, 5, 6) and having a supply opening (24) for products to be decontaminated, the distributor chamber (11) comprising distributor means (15) for distributing the products to the different decontamination chambers (3, 4, 5, 6), and the decontamination device (1) comprising a discharge chamber (12) disposed downstream of the decontamination chambers (3, 4, 5, 6) and having a discharge opening (2) and comprising transport means (16) for transporting the decontaminated products out of the decontamination chambers (3, 4, 5, 6), the distributor chamber (11) and/or the discharge chamber (12) being assigned means (17) for reducing a decontamination agent concentration by means of which the decontamination agent is conveyed through a catalytic converter in air circulation mode and/or decontamination agent is displaced by supplying fresh air.

A continuous flow sterilization system includes an inclined treatment chamber having a first end and a second end. An ozone generator generates a flow gas containing ozone; an input opening to receive a bulk material into the treatment chamber. An input port is provided for introducing the flow gas containing of ozone into the treatment chamber. A first sensor measures a level of ozone in the gas output of the treatment chamber. The other sensors measure ozone concentration and temperature within the treatment chamber. An output opening provides an exit for the bulk material. An output port provides an exit for the flow gas. An auger is disposed within the treatment chamber to move the bulk material through the treatment chamber.

The present disclosure discloses a container sterilization device and system, an assembling method and use thereof. The container sterilization device includes a sterilization gas supply assembly, a gas circulation assembly, and a heating and humidification assembly. The sterilization gas supply assembly includes a chemical feeding pipeline. The gas circulation assembly includes a gas circulation pipeline, a gas extraction pipeline, and a vacuum pump disposed on the gas extraction pipeline. The heating and humidification assembly includes a thermostatic water tank, a steam generator, a first connecting pipeline, and a humidity feeding pipeline. The first connecting pipeline is configured to provide fluid communication between the thermostatic water tank and the steam generator, while the humidity feeding pipeline is configured to be in fluid communication with the steam generator. The chemical feeding pipeline, the gas circulation pipeline, and the gas extraction pipeline are each at least partially located in the thermostatic water tank.

An apparatus for the inactivation of airborne pathogens and pathogens on the surface of an object. The apparatus including a housing with an intake region and an exhaust region and an airflow path disposed between the intake and exhaust regions. The apparatus also includes a space within the housing for placement of the object as well as an intake fan and an oxidant generator proximate the intake fan. The apparatus includes an air filter disposed in the airflow path for removing particulates and pathogens and passes the intake air through either or both of an activated carbon filter and a catalyst to convert the oxidant into oxygen.

System and method to reduce risk of exposure to pathogens using a system comprising transportable clinical chambers, often configured with the exterior dimensions of a shipping container. The transportable chamber can be partially or completely self-contained, and configured for rapid transport and setup. The chamber is typically equipped with suitable automatic airborne sterilizing agent generators, sensors, mechanisms, and automatic air control devices. After suitable safety checks, the system isolates the interior air from external air, and activates an air phase anti-microbial agent generator, filling at least a portion of the chamber with an air-phase anti-pathogen agent. After sterilization, the invention deactivates the generator and then restores the connection to outside sterilized air. In some embodiments, the transportable chamber also comprises an intelligent platform comprising video cameras, and computer vision systems configured to identify humans and medical supplies, read optical tags, and correlate recognized objects with RFID tag data.

Disclosed is a process and a device for sterilizing gas filtration unit, characterized in that the sterilization process includes at least: an application step consisting in circulating, through the gas filtration unit, a gas mixture including hot air and a determined amount of hydrogen peroxide vapor, in which the determined amount of hydrogen peroxide vapor is obtained by sequentially injecting, with a given time interval (t) between two successive injections, a given dose of hydrogen peroxide in the liquid state into the hot air; anda sterilization step consisting, during the time interval (t), in circulating hot air through the filtration unit in order to eliminate, by evaporation, all or some of the hydrogen peroxide deposited on the filtration unit during the application step.

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 method of sterilizing material includes receiving the material in a sterilizing chamber, vaporizing sterilant supplied to vaporizer from a sterilant source, exposing the material to the vaporized sterilant by conducting a sterilization cycle in the sterilizing chamber, heating ambient filtered air supplied to the vaporizer from an ambient filtered air source, and removing residuals of the vaporized sterilant absorbed or adsorbed by the material during the sterilization cycle by conducting an aeration cycle in the sterilizing chamber. The removing of the residuals includes conducting a plurality of aeration pulses to provide the sterilizing chamber with an aeration atmosphere comprising the heated filtered air to vaporize the absorbed or adsorbed residuals, and conducting a plurality of aeration vacuum pulses to evacuate the aeration atmosphere and vaporized residuals from the sterilizing chamber.