A HVAC air treatment (HAT) system/method for use in heating, ventilation, and air conditioning (HVAC) systems that incorporates an air flow sensor (AFS), timer control unit (TCU), ultraviolet lamp(s) (UVL), lamp feedback indicator (LFI), liquid distribution atomizer (LDA), leak exhaust fan (LEF), and digital control processor (DCP) is disclosed. The AFS indicates detection of air flow within the HVAC ducts (HVD) to the DCP and may wirelessly communicate with the DCP. The DCP interrogates the TCU to determine when HAT is to occur if HVD air flow is detected and activates the UVL to disinfect air within the HVD. The LFI provides feedback to the DCP to verify that the UVL is operational. The UVL may be positioned at the fresh air intake (FAI), air intake plenum (AIP), evaporator/heat exchanger (HEX), and/or air exhaust plenum (AEP) and may incorporate an adjustable magnetic frame (AMF) allowing UVL retrofit installation.

A fluid treatment device includes a photocatalytic filter for deodorizing and sterilizing a fluid; a frame for fixing the photocatalytic filter; and a light source unit coupled to the frame. The light source unit includes a light source support member and a light emitting diode, which is provided on the light source support member so as to emit light at the photocatalytic filter. The frame and the light source support member are coupled in a form that separates the photocatalytic filter from the light emitting diode.

A fluid treatment device includes a photocatalytic filter for deodorizing and sterilizing a fluid; a frame for fixing the photocatalytic filter; and a light source unit coupled to the frame. The light source unit includes a light source support member and a light emitting diode, which is provided on the light source support member so as to emit light at the photocatalytic filter. The frame and the light source support member are coupled in a form that separates the photocatalytic filter from the light emitting diode.

A sensor system for identifying potential bullying and presence of a moving object at a site includes a sound sensor configured to sense sounds at the site, a motion sensor configured to detect a motion at the site, a sterilizer configured to sterilize air in the site, and a controller configured to identify potential bullying based on the sensed sound, identify presence of the moving object at the site based on the sensed sound or detection of the motion, and supply power to the sterilizer based on the identification.

A sensor system for identifying potential bullying and presence of a moving object at a site includes a sound sensor configured to sense sounds at the site, a motion sensor configured to detect a motion at the site, a sterilizer configured to sterilize air in the site, and a controller configured to identify potential bullying based on the sensed sound, identify presence of the moving object at the site based on the sensed sound or detection of the motion, and supply power to the sterilizer based on the identification.

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.

An air sanitizing system is provided. The air sanitizing system includes a dispensing device configured to dispense a sanitizing composition into liquid particles and vapor. The air sanitizing system also includes a fan that is configured to disperse the vapor of sanitizing composition into the air. The air sanitizing system includes a filtering device configured to remove at least a portion of the liquid particles.

An air sanitizing system is provided. The air sanitizing system includes a dispensing device configured to dispense a sanitizing composition into liquid particles and vapor. The air sanitizing system also includes a fan that is configured to disperse the vapor of sanitizing composition into the air. The air sanitizing system includes a filtering device configured to remove at least a portion of the liquid particles.

The present invention provides for a system for disinfecting air circulated in an HVAC system. The system includes an interchangeable filter located in a filter housing. The filter housing connects two segments of ductwork. The filter housing is contoured to align with perimeter dimensions of each of said two segments of ductwork. The filter housing defining a four-walled metallic segment with openings correlating to each of said two segments of ductwork. A closeable opening provides for insertion of the interchangeable filter therein created by a hinge moveably coupling one wall of said four-walled metallic segment thereby creating a hinged flap, whereby once closed, the flap seals an inside airflow channel between each ductwork segment connected by said four-walled metallic segment.