The formation of sterilization tubes by plates with parts that match in whole or in part, that when assembled together form ducts, passages, channels, or tubes in a mass or block of heat resistant material. The size of the block may be reduced by forming the ducts as curved passages or tubes that will keep or increase the length of the tube while keeping the same or more exposure time while the gas is passing through. If the length of the curved duct is the same as a straight tube would have been, the overall size of the assembly may be reduced from what it otherwise would have been. If the curved length is made longer while the size of the assembly is kept the same, the exposure time is increased for a more effective sterilization.

The invention provides a system for sanitizing fluids such as water and air. In particular, the invention provides a combination of solid chlorhexidine and a polymer matrix, for which effluents are essentially free of leached chlorhexidine. The systems enable rapid disinfecting of fluids, including in line at the point of use, and can be employed for both high volume applications and disposable single-use applications.

Embodiments provide an aeromedical bio-containment module for use in a cargo plane. The aeromedical bio-containment module includes a fully integrated pallet system allowing for the module to roll onto the cargo plane. An integrated set of lugs allows the module to be locked into the cargo plane floor without the use of chains or other pallets. The aeromedical bio-containment module features a ward area for safe treatment of patients, an anteroom, and an office area for personnel. The aeromedical bio-containment module operates under a negative pressure system, and includes a full air filtration system to remove pathogens, particulates, and other airborne contaminants.

An air pollution prevention device applied for a baby carriage includes a sealing cover, a filtration cleaner, a gas detection module and an intelligent control and process device. The sealing cover is hooded on the baby carriage for forming a sealed space. The filtration cleaner penetrates the sealing cover form the outside of the baby carriage for introducing an outside air into the sealed space of the baby carriage and discharging an air pollution source out of the sealed space. The gas detection module detects the air pollution source and outputs gas detection data. The intelligent control and process device receives and compares the gas detection data and controls an enablement of a gas guider of the filtration cleaner for filtering and exchanging the air pollution source in the sealed space so as to generate a clean air.

Within examples, a system to provide filtered air to an enclosure for a passenger of a vehicle is described that includes a collapsible canopy hood attachable to a support structure of a vehicle, and a filter unit mounted to the support structure of the vehicle and having an output coupled to the collapsible canopy hood. The filter unit includes an air filtration component to filter air that is then output to the collapsible canopy hood.

An airborne pathogen extraction system that provides for continuous airborne pathogen particle extraction from a specifically targeted area in a room or a specifically targeted area proximate to a user. The pathogenic particles are filtered and/or disinfected before the air is returned proximate to the originating location, or are directed an area away from the user(s). The airborne pathogen extraction systems and methods lower the chances of contagion or infection from airborne pathogens, such as viruses.

Air purification devices include an air inlet and outlet, upstream and downstream sections in air flow communication with the air inlet and outlet and a filter removably positioned between the upstream and downstream sections to filter at least pathogens from air being passed through the filter. One or more ultraviolet (UV) illuminating sources may be positioned in at least the upstream section proximate the filter to illuminate at least an upstream surface of the filter with sufficient UV radiation to kill viable pathogens that accumulate on the filter. One or more ozone generating sources may be positioned to generate ozone in sufficient concentrations to kill viable pathogens proximate the device. The UV illuminating sources and ozone generating sources may be positioned to provide a predetermined pressure drop across the sources and air flow pattern proximate the filter, and enable the filter to be removed without handling the sources.

A self-cleaning air conduit for deactivating and decomposing chemical and life based airborne contamination. The conduit contains ultraviolet (UV) sources that irradiate semi UV reflective surfaces within the conduit. Said conduit is positioned in the path of pre and post filters. The internal surfaces of the conduit and components cast be altered by chemical and or mechanical means to maximize surfaces area and adhesion of photocatalytic coatings. Multiple coated panels within the conduit can be configured parallel to the air flow and positioned to enhancer the interaction of UV radiation with airborne contamination and photocatalytic produced free radical. Microprocessor based electronics connected to the conduit, provide power for key internal and ancillary componence necessary to control and monitor air velocity, UV radiation levels and airborne contamination levels. Pre and post filters can be positioned to retain VOC and deactivated life based airborne contamination and inert mineral based contamination.

A method of monitoring indoor environments for aerosolized pathogens includes: (a) receiving a pathogen status for each of a plurality of aerosol samples collected by a plurality of corresponding air treatment devices; (b) determining whether the pathogen status for each aerosol sample changes a safety status of a corresponding indoor environment from which the aerosol sample was collected; and (c) in response to determining a change in the safety status, generating a notification associated with the change in the safety status for the corresponding indoor environment.

An improved technology for inactivation of viruses, for example the SARS-CoV-2 virus that is causing the Covid-19 pandemic, is described. The technology can include a device that includes a substrate coated in a polymer that is infused with a pathogen inactivating material. In various embodiments, at a given time, a portion of the pathogen inactivating material is exposed to the environment, and the device is configured to periodically or intermittently expose additional pathogen inactivating material to the environment. For example, the polymer can be ablative or sacrificial.