A ventilation system includes a line system which is designed to guide an air stream and to provide the air stream during normal operation via an outlet of the line system for supplying a space. The ventilation system includes a generating unit which is designed to produce reactive oxygen species during a cleaning operation and to feed the same to the air stream conducted in the line system. Also disclosed are methods for operating such a ventilation system and a generating unit for such a ventilation system.

Provided is an autoclave for medical-dental instruments and the like, including a sterilization chamber, an accumulator, a main channel connecting the sterilization chamber and the accumulator in circuit and bringing them into communication for fluid passage, a pump adapted to move the fluid inside the main channel, in which the accumulator includes a volume of a material having hygroscopic properties resulting from an exothermic reaction and vice versa.

The present invention relates to a device for isolating and cleaning contaminated components comprising a chamber, an entrance door through which components to be isolated and cleaned are introducible into the chamber, means configured to deliver washing solution into the chamber and onto the components to be cleaned, a drying system configured to dry the chamber as well as its content, wherein the device further comprises an exhaust filter system attached to the air exhaust of the chamber, the exhaust filter system comprising a pipe, at least one filter and a blower, the exhaust filter system being configured to be able to bring the chamber under a pressure lower than atmospheric pressure by means of the blower all the time the chamber is closed. The present invention also relates to a corresponding method for isolating and cleaning contaminated components with the aforementioned device.

An apparatus for treating air includes a housing with an air inlet and an air outlet, the housing enclosing an air treatment zone and an ozone removal zone, wherein the ozone removal zone is positioned downstream of the air treatment zone with respect to a flow direction of the air being treated, an ultraviolet (UV) light source in the air treatment zone configured to generate ozone from the air, wherein the UV light from the UV light source and the ozone generated by the UV light source treat the air in the air treatment zone, catalyst in the ozone removal zone that removes at least a portion of the ozone generated by the UV light source, and an air mover positioned near the air outlet configured to draw the air through the air inlet into the air treatment zone from outside the housing.

A method for controlling condensation of hydrogen peroxide at a preselected temperature within a sealed sterilization chamber including an article to be sterilized includes the steps of applying to the sealed chamber a vacuum of a first pressure sufficient to evaporate, at the preselected temperature, an aqueous solution of hydrogen peroxide of a first concentration. The hydrogen peroxide solution is then evaporated into a water vapor component and a hydrogen peroxide vapor component. The evaporated solution is injected into the sealed chamber in repeated pulses. The injecting is terminated once a preselected second pressure, higher than the first pressure, is reached in the chamber. The pulse volume is selected to allow selective control of the condensation of the hydrogen peroxide vapor component to achieve a layer of micro-condensation of hydrogen peroxide on the article, which layer has a second hydrogen peroxide concentration higher than the first hydrogen peroxide concentration.

Disclosed is an incubator shaker (1) for cell cultivation, which comprises an incubation chamber (10), a shaking table (21) disposed in the incubation chamber (10), and an ozone distributing device (100) for distributing ozone in the incubation chamber (10) including a space underneath the shaking table (21). The shaking table (21) is configured to place a cultivation container thereon during a cultivation process. This incubator shaker (1) can be used for a further disclosed method for decontaminating the incubator shaker (1), including the steps of placing the ozone distributing device (100) into the incubation chamber (10), guiding ozone into the incubation chamber (10), and conveying the ozone inside the incubation chamber (10) including a space underneath the shaking table (21).

A system comprises an ozone conduit in fluid communication with an aircraft door seal configured to seal the ozone conduit to an aircraft door. An ozone source is in fluid communication with the ozone conduit for supplying a flow of ozone gas (O.sub.3) to an aircraft interior through the ozone conduit and aircraft door seal. The ozone conduit can be an ozone inlet line, and an ozone outlet line can be in fluid communication with the aircraft door seal for removal of ozone from the aircraft interior.

Disclosed is a method of sterilizing an article by sequentially exposing the article under vacuum first to a gaseous conditioning agent for forming radicals and then to a sterilant. The preferred conditioning agent is hydrogen peroxide and the preferred sterilant is ozone. The chamber is initially evacuated to a first vacuum pressure and then sealed for the remainder of the sterilization process and during all sterilant injection cycles, without removal of any component of the sterilization atmosphere, which means without any measures to reduce the water vapor content. Keeping the chamber sealed and maintaining the conditioning agent and the radicals generated thereby in the chamber for the sterilization with sterilant results in a synergistic increase in the sterilization efficiency and allows for the use of much lower sterilant amounts and sterilization cycle times than would be expected from using the conditioning agent and the sterilant in combination.

This document describes self-cleaning devices. In one aspect, a self-cleaning device includes a fabric having a surface covered with a photocatalyst, one or more light sources embedded in the fabric, and a triggering mechanism that activates a cleaning cycle by activating the one or more light sources. The triggering mechanism can include a pressure sensor. The triggering mechanism can be configured to activate the cleaning cycle in response to detecting a decrease in pressure being applied to the pressure sensor.

The following disclosure relates to a home plasma sterilizer that sterilizes household items in a home by using plasma. According to an embodiment, there is provided a home plasma sterilizer including: a plurality of plasma electrode modules configured to generate plasma in order to sterilize a sterilization target object inside a sterilization chamber; a harmful gas removal unit configured to communicate with the sterilization chamber, and provided with a catalytic filter that is intended to remove harmful gas inside the sterilization chamber; a power supply unit configured to supply power to the plasma electrode modules; and a control unit configured to control the supply of power by the power supply unit; wherein the control unit performs control so that the plurality of plasma electrode modules is sequentially supplied with power at predetermined cycles but the supply of power is continuous as a whole.