The disclosure describes a method for disinfecting an aircraft cabin that includes injecting a non-peroxide disinfectant into an environmental control system of an aircraft and discharging cabin supply air through the environmental control system to discharge the non-peroxide disinfectant into the aircraft cabin. In some instances, the method includes aerosolizing the disinfectant into a plurality of liquid droplets while injecting the disinfectant into the environmental control system. In some instances, the injected disinfectant includes a non-corrosive, non-toxic disinfectant, such that the disinfectant may be discharged into the aircraft cabin in the presence of personnel in the aircraft cabin.

A cleaning device includes a housing, an air driver, an ozone generator, and a catalyst. The housing defines an internal cavity. The housing has a first portion defining a first chamber of the internal cavity, a second portion defining a second chamber of the internal cavity, and an intermediate portion extending between the first portion and the second portion, and defining an intermediate chamber. The first chamber is connected to an inlet of the housing. The first portion having a first width. The second chamber is connected to an outlet of the housing. The second portion has a second width greater than the first width. The first portion, the intermediate portion, and the second portion are linearly aligned along a longitudinal axis of the housing. The air driver is positioned within the first chamber. The ozone generator is positioned within the intermediate chamber. The catalyst is positioned within the second chamber.

A cleaning device includes a housing, an air driver, an ozone generator, and a catalyst. The housing defines an internal cavity. The housing has a first portion defining a first chamber of the internal cavity, a second portion defining a second chamber of the internal cavity, and an intermediate portion extending between the first portion and the second portion, and defining an intermediate chamber. The first chamber is connected to an inlet of the housing. The first portion having a first width. The second chamber is connected to an outlet of the housing. The second portion has a second width greater than the first width. The first portion, the intermediate portion, and the second portion are linearly aligned along a longitudinal axis of the housing. The air driver is positioned within the first chamber. The ozone generator is positioned within the intermediate chamber. The catalyst is positioned within the second chamber.

Technologies for sanitizing medical devices are described. In particular, sanitizing systems, components of sanitizing systems, and methods for sanitizing medical devices such as continuous positive airway pressure (CPAP) equipment are described. In embodiments, the sanitizing systems include a sanitizing gas generator and a base including at least one exhaust port and a filter.

A system including a passenger area of a vehicle, an air distribution system arranged in fluid communication with the passenger area, and a fluid movable through the air distribution system to the passenger area, the fluid having a cleaning agent entrained therein.

A modular environment modification device receives different cores for performing different functions such as dispensing decontaminant agents. These cores are contained within a housing that can communicate with other like devices and with remote devices such as iOS or Android powered smart devices. Communication between multiple like devices provides the ability to accommodate spaces of varying size. Sensors within each device monitor the environment, sense temperature and pressure, the presence of certain pathogens, and sound. Sensed information is used by the device to make decisions, like suspension of the decontamination process. Sensed information is sent to smart devices which perform various interfacing or data collection functions.

This application discloses a wearable member. The wearable member includes a main body, a gas emitter, and a light source, where the main body includes a first body and a second body; the first body and the second body jointly define a target region; the gas emitter and the light source are disposed in the main body; the gas emitter emits gas to the target region; the light source emits a light beam to the target region; and an overlapped region between a region including the gas and a region including the light beam is used to display an image.

This application discloses a wearable member. The wearable member includes a main body, a gas emitter, and a light source, where the main body includes a first body and a second body; the first body and the second body jointly define a target region; the gas emitter and the light source are disposed in the main body; the gas emitter emits gas to the target region; the light source emits a light beam to the target region; and an overlapped region between a region including the gas and a region including the light beam is used to display an image.

The invention describes a ceiling-mounted ozone-generating device (1) which comprises: at least one ozone-generating element (2); a fan (3) arranged in a position adjacent to the ozone-generating element (2) to propel the ozone generated by the ozone-generating element (2) outwards; a processing means (4) that controls the operation of the ozone-generating element (2) and the fan (3); and a housing which comprises a cover (5a) and a base (5b) that houses the ozone-generating element (2), the fan (3), and the processing means (4), wherein the housing comprises an air inlet hole (6) and an ozone outlet hole (7). Additionally, the casing comprises means for fixing it to the ceiling of a room.

An antimicrobial device (50) includes an antimicrobial unit (60), an ion unit (70), and a control unit (80). The antimicrobial unit (60) delivers at least one of light having an antimicrobial effect, a gas having an antimicrobial effect, or liquid particles having an antimicrobial effect toward a target space (14). The ion unit (70) delivers ions toward the target space (14). The control unit (80) controls the antimicrobial unit (60) and the ion unit (70). Each of the antimicrobial effect of the light, the antimicrobial effect of the gas, and the antimicrobial effect of the liquid particles is stronger than an antimicrobial effect of the ions.