Disclosed is a catalyst filter, which includes a catalyst support and a nano metallic catalyst sprayed to a surface of the catalyst support. The catalyst filter uses catalyst slurry prepared by using a particulate catalyst, in which a small amount of nano metallic catalyst exhibiting a catalyst performance is sprayed to a surface of the catalyst support, different from an existing patent technique in which catalyst particles are formed and prepared as a support to consume a large amount of catalyst. Therefore, the specific surface area of the catalyst filter is not smaller than the specific surface area of the nano catalyst particles, and thus the catalyst filter may effectively remove and decompose ultra-low concentration gas-state contaminants in an indoor air.

An ionic oxidation refreshing system for refreshing an odorized item, comprising an enclosure with an airflow system to contact the odorized item on all sides; an ionization system that produces a positively charged ionized ozone gas mixture inside of the enclosure, killing germs, including odor-causing bacteria, viruses, molds, and fungus, and provides the odorized item inside the enclosure with a net positive charge; a filter that neutralizes and filters out any toxic by-products; an electrostatic liquid atomization system that creates a fine mist of a quick-cleaning solution, and, in conjunction with the airflow system, causes solution droplets to penetrate deep into the odorized item and agitate a surface of the odorized item, ensuring the formula is evenly delivered onto the odorized item without over saturating any area.

The present invention relates to a reefer container for transporting and storing a plurality of produce at a predetermined temperature, the produce generating ethylene and other organic compounds during transport and storage, said reefer container comprising a substantially closed room having an atmosphere, a cooling device for maintaining the room at the predetermined temperature, and an atmosphere-controlling system (14) for controlling the atmosphere in the room of the reefer container, the atmosphere-controlling system comprising a system inlet (161) and a system outlet (162), a flow direction (165) of an airstream being defined between the system inlet and the system outlet, a fan (160) arranged at the system outlet, an ethylene reduction unit (100) for reducing a content of ethylene of the atmosphere in the room, a catalyst unit (150) arranged downstream the ethylene reduction unit, the catalyst unit being adapted to reduce a content of ozone generated during the reduction of ethylene, the catalyst unit having a catalyst inlet (153), a catalyst outlet (154) and a catalyst midsection (155) arranged substantially between the catalyst inlet and catalyst outlet, and a control unit (200), wherein a first measuring point (103) is arranged upstream the catalyst inlet and a second measuring point (151) is arranged at the catalyst midsection, the first measuring point and the second measuring point being connected with at least a first ozone sensor (170) so that via the first measuring point a first ozone concentration (C1) of the air before the air enters the catalyst unit can be measured, and via the second measuring point a second ozone concentration (C2) of the air present in the catalyst midsection of the catalyst unit can be measured, the first ozone sensor being connected with the control unit, and wherein the first ozone concentration (C1) is compared to the second ozone concentration (C2) in the control unit in order to calculate the expected ozone concentration of the air downstream the catalyst unit and the efficiency of the catalyst section. Further, the present invention relates to a method for measuring an ozone concentration in an airstream in a reefer container according to the present invention.

Apparatus comprising: a fumehood; and an air treatment device for purging unwanted substances from the exhaust air of the fumehood, the air treatment device comprising: a non-thermal plasma reactor stage for producing air byproducts comprising O, N, OH and O.sub.3 and introducing those air byproducts into the exhaust air of the fumehood so as to treat the exhaust air of the fumehood; and a catalyst stage downstream of the non-thermal plasma reactor stage for further treating the air downstream of the non-thermal plasma reactor stage.

An air separation system includes a feed air line for transporting feed air and an air separation module with a polymeric membrane. The air separation module is configured to receive feed air through the feed air line and separate the feed air into nitrogen-enriched air and oxygen-enriched air. The air separation system further includes a gaseous contaminant removal system upstream of the air separation module and configured to remove gaseous contaminants from the feed air received by the air separation module, and a nitrogen-enriched air line for transporting the nitrogen-enriched air from the air separation module to a fuel tank for inerting.

The invention relates to an amperometric electrochemical gas sensing apparatus for sensing NO.sub.2 and O.sub.3 in a sample gas and a method of using same. The apparatus comprises: a first working electrode which is a carbon electrode and at which both NO.sub.2 and O.sub.3 are reducible to thereby generate a current; a second working electrode which is a carbon electrode and at which NO.sub.2 is reducible to thereby generate a current; and an O.sub.3 filter material comprising 1-20% MnO.sub.2 by weight mixed with binder and adjacent the second working electrode, and said apparatus is configured such that, in operation, the first working electrode and the O.sub.3 filter are exposed to the sample gas in parallel.

A high efficiency ultra-violet air purification system is disclosed. The system includes an apparatus for purifying air. The apparatus includes a chamber having a hollow interior and having an inlet and an outlet, the chamber having an inner reflective surface. The apparatus further includes an ultraviolet (UV) light source mounted within the hollow interior of the chamber between the inlet and the outlet. The apparatus further includes a honeycomb structure mounted to each of the inlet and the outlet of the UV chamber, the honeycomb structure having an array of hexagonal passages that are orthogonal to the inner reflective surface of the chamber, each hexagonal passage being at least partly coated with a UV catalyst and a UV light absorption coating.

A gas processing apparatus of an embodiment has stacks, gas flow paths, an AC power supply, and a flow limiter. The stacks are away from each other and in parallel. Each stack includes a dielectric substrate and a first to a third electrode. The first and second electrodes are respectively disposed on the first and second main surfaces of the dielectric substrate. The third electrode is disposed inside the dielectric substrates. The gas flow paths supply a target gas between the stacks, The AC power supply applies an AC voltage across the first and second electrodes and the third electrodes, so as to generate plasma induced flows of the target gas between the dielectric substrates. The flow limiter is disposed on a downstream side of the stacks and limits a flow rate of the target gas.

An air cleaning device (1) in a containment, especially isolator, is provided which includes a catalyst (2) which is disposed on a surface of a porous support (3) and is covered by a grid, preferably on both sides, in a flow cross section (5). The air cleaning device is used for elimination of hydrogen peroxide. A containment in which the air cleaning device (1) is incorporated into the circulation circuit of the containment is also provided.

An apparatus and method for inactivation of airborne pathogens to include a reactor space with an intake opening, an exhaust opening, and an airflow path disposed between the intake and exhaust openings for air to continuously transit throughout the reactor space. The apparatus also includes at least one of (i) a corona discharge unit with a pressure swing adsorption unit, or (ii) a UV-C germicidal lamp to generate a sufficient concentration of ozone and UV light to inactive pathogens. The apparatus also includes a catalyst disposed within the path of the airflow to convert ozone to oxygen following the inactivation step and an adsorbent to remove nitrogen oxides from the air. The apparatus also includes sensors for measuring ozone and nitrogen oxides concentrations at the exhaust opening.