A system or method utilizes one or more outside sensors to measure one or more outside air parameters, and optionally one or more inside sensors to measure inside air parameters. A processor is configured to at least partially control the operation of an air cleaner based on at least one of the one or more outside air paraments, or a comparison of at least one of the one or more outside air parameters to at least of one of the one or more inside air parameters. The system and method may use artificial intelligence to provide additional information to the controller to assist in controlling the air cleaner.

A multi-function air purifying and sterilizing system for filtering and/or sterilizing air comprises: (a) a casing having an air inlet at one end of the casing and an air outlet at the other end of the casing, (b) electrostatic means for attracting particulate matter including biological contaminants, and thus, for removing the particulate matter and the biological contaminants from an air stream passing therethrough, the electrostatic means comprising at least one spiked surface, the at least one spiked surface inducing corona discharge and/or cold plasma when high voltage is applied, the corona discharge and/or the cold plasma producing ozone molecules, (c) at least one energy source for producing rays, the at least one energy source is inter-displaced within the electrostatic means to have the produced rays in close proximity to the electrostatic means for maximizing the at least one energy source efficiency in demolishing the particulate matter and the biological contaminants depositing on the electrostatic means, and/or converting the ozone molecules to hydroxyl radicals, the hydroxyl radicals disinfecting and inhibiting the biological contaminants and/or odors, and/or gases in the air stream, the hydroxyl radicals is spreadable within a confined space, thus, disinfecting biological contaminants and/or odors, and/or gases within a confined space.

A multi-function air purifying and sterilizing system for filtering and/or sterilizing air comprises: (a) a casing having an air inlet at one end of the casing and an air outlet at the other end of the casing, (b) electrostatic means for attracting particulate matter including biological contaminants, and thus, for removing the particulate matter and the biological contaminants from an air stream passing therethrough, the electrostatic means comprising at least one spiked surface, the at least one spiked surface inducing corona discharge and/or cold plasma when high voltage is applied, the corona discharge and/or the cold plasma producing ozone molecules, (c) at least one energy source for producing rays, the at least one energy source is inter-displaced within the electrostatic means to have the produced rays in close proximity to the electrostatic means for maximizing the at least one energy source efficiency in demolishing the particulate matter and the biological contaminants depositing on the electrostatic means, and/or converting the ozone molecules to hydroxyl radicals, the hydroxyl radicals disinfecting and inhibiting the biological contaminants and/or odors, and/or gases in the air stream, the hydroxyl radicals is spreadable within a confined space, thus, disinfecting biological contaminants and/or odors, and/or gases within a confined space.

A disclosed system includes one or more ozone generators disposed and a fluid mixer configured to inject ozone generated by the one or more ozone generators into water received from a water source via a water inlet to produce an aqueous ozone solution that is output via an aqueous ozone solution outlet. The aqueous ozone solution outlet is fluidically coupled to a splitter. The system further includes a janitorial fill station with a first faucet fluidically coupled to a first output of the splitter and configured to dispense a first portion of the aqueous ozone solution, a carbon filter fluidically coupled to a second output of the splitter and configured to reduce an ozone concentration of a second portion of the aqueous ozone solution to produce purified water for consumption, and a second faucet fluidically coupled to the carbon filter and configured to dispense the purified water.

An air-conditioning system has a filter slot in which a replaceable filter can be held. An air-treatment device in the air-conditioning system can be introduced into the filter slot through a service opening of same provided in an inlet region of the filter slot and can be mounted and fixed on at least one edge delimiting the service opening of the filter slot.

An air-conditioning system has a filter slot in which a replaceable filter can be held. An air-treatment device in the air-conditioning system can be introduced into the filter slot through a service opening of same provided in an inlet region of the filter slot and can be mounted and fixed on at least one edge delimiting the service opening of the filter slot.

An air treatment device includes: a casing having an inlet through which air is drawn, and an outlet out of which the air drawn through the inlet is blown; a blade configured to adjust a direction of the air blown out of the outlet; and a generator configured to generate an antimicrobial element that sanitizes the blade. The blade has a first surface, and a second surface opposite to the first surface. The blade is shiftable between a first position in which the antimicrobial element is provided to the first surface and a second position in which the antimicrobial element is provided to the second surface.

An air treatment device includes: a casing having an inlet through which air is drawn, and an outlet out of which the air drawn through the inlet is blown; a blade configured to adjust a direction of the air blown out of the outlet; and a generator configured to generate an antimicrobial element that sanitizes the blade. The blade has a first surface, and a second surface opposite to the first surface. The blade is shiftable between a first position in which the antimicrobial element is provided to the first surface and a second position in which the antimicrobial element is provided to the second surface.

Disclosed is a piece of furniture for air purification in the form of a substantially closed cabinet including: an upper purpose tray; side walls in vertical alignment below this tray; an opening in the top of the side walls; an opening in the bottom of the cabinet, in which an opening allows the filtered air to exit; an electrical power source; an air pressurizer connected to the power source, allowing the air to flow through the cabinet; a horizontal filter, parallel to the upper purpose tray and upstream of the air pressurizer; a vertical filter, perpendicular to the upper purpose tray downstream of the air pressurizer, at least 3 cm away from the nearest side wall; a duct between filter downstream of the air pressurizer and the nearest side wall, which duct allows the filtered air to be discharged towards the opening of the bottom part of the cabinet.

Disclosed is a piece of furniture for air purification in the form of a substantially closed cabinet including: an upper purpose tray; side walls in vertical alignment below this tray; an opening in the top of the side walls; an opening in the bottom of the cabinet, in which an opening allows the filtered air to exit; an electrical power source; an air pressurizer connected to the power source, allowing the air to flow through the cabinet; a horizontal filter, parallel to the upper purpose tray and upstream of the air pressurizer; a vertical filter, perpendicular to the upper purpose tray downstream of the air pressurizer, at least 3 cm away from the nearest side wall; a duct between filter downstream of the air pressurizer and the nearest side wall, which duct allows the filtered air to be discharged towards the opening of the bottom part of the cabinet.