Implementations of the disclosed subject matter provide a method of moving, using a drive system, a mobile robot within an area. Detecting, using at least one sensor of the mobile robot, at least one of air within the area, a surface within the area, and/or an object within the area. The area may be mapped in three dimensions based on the detecting of at least one of the air, the surface, and the object as the mobile robot moves within the area. Ultraviolet (UV) light may be emitted from a light source of the mobile robot to disinfect at least a portion of the area. A representation of the emission of the UV light may be plotted onto the mapped area to generate an exposure plot, where the representation is of the UV light emitted on at least one of the air, the surface, and the object in the area.

A building automation system may control ultraviolet lights to intelligently disinfect susceptible environments based on occupant density. The system comprises multiple occupancy sensors, a disinfection environment tracking engine, and an ultraviolet light control engine. The multiple occupancy sensors generate real time occupancy data associated with multiple objects detected within an area. The disinfection environment tracking engine determines real time occupant density of the multiple objects detected within the area based on the real time occupancy data generated by the multiple occupancy sensors. The ultraviolet light control engine controls operation of one or more ultraviolet lights to disinfect the area based on the real time occupant density determined by the disinfection environment tracking engine.

This description relates to waste disposal garbage chutes and more particularly to automated air quality management in and around the disposal chute and collection rooms where garbage chutes are present utilizing automated air quality sensing hardware and evacuation devices to provide a clean, sanitary waste room environment. A system according to the present invention includes a 3 step design using an air sensor to determine air cleaning cycle, and an air intake port with specular reflective surfaces in the inside to provide a reflective element to reflect UV light into the airborne particulates thereby killing 99% of the bacteria and fungi before entering an electrified gravity fed fluid filament air filter which collects the dead bacteria and fungi and settles in a collection reservoir. The fluid in the reservoir is then further filtered to clean the fluid for reuse in the automated air cleaning system.

The air sterilization device with heating apparatus comprises a mainframe, a sterilization system, a heating system, circuits and a control system and a housing. The sterilization system includes an ultraviolet sterilization apparatus to sterilize and disinfect air; the heating system heats the air to inactivate virus; and the housing has an air inlet and an air outlet. Air can circulate into the housing through the air inlet with the action of mainframe and then the air is discharged from the air outlet into a room after the disinfection and sterilization processes are finished. The device with heating apparatus aims at the secondary inactivation of viruses by high temperature after the sterilization and disinfection processes are finished by ultraviolet sterilization apparatus and heating system, and at the decomposition of ozone produced in the process of ultraviolet disinfection to eliminate secondary air pollution by ozone.

A modular patient lift system includes a ceiling grid, a plurality of rails, a gantry configured to traverse the ceiling grid via the plurality of rails, and a patient lift coupled to the gantry and configured to traverse the ceiling grid with the gantry. The modular patient lift system further includes one or more sensors provided on at least one of the plurality of rails, the gantry, and the patient lift, the one or more sensors configured to collect at least one of environmental data and position data.

A tissue box with an atomization function is provided, which includes a box body. A tissue chamber and a disinfection chamber are formed in the box body; the box body is also provided with a tissue outlet and a disinfection lamp; the tissue box also includes an atomization assembly and a control assembly; the atomization assembly is provided with an atomization nozzle; the box body is provided with an atomization port which is communicated with the atomization nozzle of the atomization assembly; a power supply is arranged in the box body; and the disinfection lamp, the atomization assembly and the power supply are all electrically connected to the control assembly.

Disinfecting systems, methods, and devices are described. An example of a disinfecting system is disclosed to include: a radiation source configured to emit a disinfecting radiation; a source wireless communication device coupled to the radiation source; a plurality of receiver wireless communication devices; and a plurality of disinfecting radiation sensors configured to detect the disinfecting radiation, wherein each of the plurality of disinfecting radiation sensors is configured to record an intensity level information of the disinfecting radiation and configured to transmit the intensity level information through one of the plurality of receiver wireless communication devices to a center controller.

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.

A photo catalytic filter is configured such that a plurality of plate-shaped members on which a photocatalyst is carried face each other with a gap therebetween, and the gaps form an air flow path. Each plate-shaped member has end surfaces respectively on an air entrance side and an air exit side of the gap. A UV irradiation unit faces the end surfaces on at least one of the air entrance side and the air exit side of the plate-shaped members, and is a predetermined distance away from those end surfaces. An air supply path for taking air from a lateral direction substantially parallel to the end surfaces, and supplying the air to the flow path, or an air discharge path for discharging the air exiting the flow path to a lateral direction substantially parallel to the end surfaces, is formed between the UV irradiation unit and the end surfaces of the plate-shaped members.

The invention relates to a multi-purpose container (1) with an air freshening function for receiving cloths (31), in particular for use in a drink holder of a vehicle. The multi-purpose container comprises a housing (10) with a lid (20) for forming a receiving space (13) in the housing (10). The lid (20) has an opening (22) for the removal of cloths (31) from the receiving space (13) and a receiving recess (21) for receiving the scented insert (40).