An air sterilizing device, comprising: a housing (100), forming an air flow path thereon; an ozone generating unit (200), generating ozone particles to be supplied to the air flow path; a filter cartridge (300), receiving ozone generated by the ozone generating unit (200) to discharge bubbles comprising ozone and hydroxyl radicals; an ultrasonic generating unit (400), connected to the filter cartridge (300) to generate ultrasonic waves; an air supply fan (500), configured to supply air to the air flow path of the housing (100); and a power supply unit, configured to supply power for driving the ozone generating unit (200), the ultrasonic generating unit (400), and the air supply fan (500).

An air sterilizing device, comprising: a housing (100), forming an air flow path thereon; an ozone generating unit (200), generating ozone particles to be supplied to the air flow path; a filter cartridge (300), receiving ozone generated by the ozone generating unit (200) to discharge bubbles comprising ozone and hydroxyl radicals; an ultrasonic generating unit (400), connected to the filter cartridge (300) to generate ultrasonic waves; an air supply fan (500), configured to supply air to the air flow path of the housing (100); and a power supply unit, configured to supply power for driving the ozone generating unit (200), the ultrasonic generating unit (400), and the air supply fan (500).

An electro-ionic device that includes an outer frame, a first conductor, an insulating frame, and a second conductor. The outer frame defines a passageway there through. The first conductor is positioned within the outer frame and includes at least one wire configured to be supplied with a voltage. The insulating frame is positioned within outer frame and forms a non-conductive barrier between the first conductor and the outer frame. The second conductor is positioned within and contacts the outer frame.

An electro-ionic device that includes an outer frame, a first conductor, an insulating frame, and a second conductor. The outer frame defines a passageway there through. The first conductor is positioned within the outer frame and includes at least one wire configured to be supplied with a voltage. The insulating frame is positioned within outer frame and forms a non-conductive barrier between the first conductor and the outer frame. The second conductor is positioned within and contacts the outer frame.

A fine water particle release device includes: a case formed in a cylindrical shape having both ends opened; a fine water particle generating element accommodated in the case and generating uncharged fine water particles; an air blowing member operating to allow air to flow into the case from one end and allow the air flowing into the case to be released from the other end; a discharge element including first and second electrodes separated from each other, the discharge element causing discharge in a discharge space between the first and second electrodes by applying a voltage between the first and second electrodes, and being disposed such that the fine water particles pass through the discharge space together with the air; and a control device controlling the discharge and a generated moisture amount generated in the fine water particle generating element.

Systems and methods for batch processing air taken from a populated environment to destroy pathogens contained therein. A multi-chamber treatment system can be coupled between one or more air return vents of the populated environment and one or more supply vents providing air into the populated environment. A filling chamber can be coupled to the air return vent(s) of the populated environment adapted to receive potentially contaminated air therefrom. An expressing chamber can include components for treating the potentially contaminated air to destroy pathogens. A relaxing chamber can allow treated air previously treated in the treatment compartment to stabilize. An exhausting chamber can be coupled to an air conditioning system serving the populated environment or the supply vent(s) providing air back into the populated environment. Treatment can be facilitated by ozone, UVC, and other means.

The present invention concerns an air treatment system for purifying room air, including an elongate carrier body, in particular a tube, of a predetermined carrier body length, wherein the carrier body is so designed that a passage extends with a passage diameter from an inlet side to an outlet side, and a ventilator unit adapted to convey room air through the passage of the carrier body from the inlet side to the outlet side with a predetermined air flow rate capacity, and an air treatment unit adapted to generate ozone in an ozone section within the passage in order to purify the room air being conveyed through the passage in the ozone section with the generated ozone and which is adapted to ionize the room air in an ionization section within the passage in order to purify the room air being conveyed through the passage in the ionization section by means of ionization.

The present invention concerns an air treatment system for purifying room air, including an elongate carrier body, in particular a tube, of a predetermined carrier body length, wherein the carrier body is so designed that a passage extends with a passage diameter from an inlet side to an outlet side, and a ventilator unit adapted to convey room air through the passage of the carrier body from the inlet side to the outlet side with a predetermined air flow rate capacity, and an air treatment unit adapted to generate ozone in an ozone section within the passage in order to purify the room air being conveyed through the passage in the ozone section with the generated ozone and which is adapted to ionize the room air in an ionization section within the passage in order to purify the room air being conveyed through the passage in the ionization section by means of ionization.

Systems and methods to treat an environment. The system includes a plurality of scent control material sources configured to output a scent control material (e.g., an oxidant) into the environment to reduce pathogens, dispose of scent molecules and their sources, and otherwise treat the environment. The system can include a controller communicatively coupled to the plurality of scent control material sources and cause one or more subsets of the plurality of scent control material sources to individually or collectively output scent control material into the environment.

Systems and methods for batch processing air taken from a populated environment to destroy pathogens contained therein. A multi-chamber treatment system can be coupled between one or more air return vents of the populated environment and one or more supply vents providing air into the populated environment. A filling chamber can be coupled to the air return vent(s) of the populated environment adapted to receive potentially contaminated air therefrom. An expressing chamber can include components for treating the potentially contaminated air to destroy pathogens. A relaxing chamber can allow treated air previously treated in the treatment compartment to stabilize. An exhausting chamber can be coupled to an air conditioning system serving the populated environment or the supply vent(s) providing air back into the populated environment. Treatment can be facilitated by ozone, UVC, and other means.