Disclosed is a method for disinfecting and cleaning to prevent contamination of a passenger vehicle, characterized in that it includes the following operations:installing at least one filter and condenser in the ventilation circuit; creating a swirling vortex of a disinfectant liquid by a gas referred to as a driving gas; spraying the swirling mixture created onto the clothing and luggage of passengers before they enter the passenger compartment; and spraying the mixture created onto the solid surfaces and/or into the air of the passenger compartment to be disinfected. Also disclosed is a device for implementing the method.

To provide a clean room facility that appropriately performs air conditioning of a clean room. The clean room facility includes: a front room and a work room that are clean rooms provided inside a large room; an air handling unit configured to adjust a temperature of air supplied to the large room; a chamber provided as one common space above a ceiling of the front room and the work room and configured to guide air from the large room; an air supply fan; and a duct shaft. The duct shafts include the duct shaft that does not communicate with the chamber, and air is guided from the front room and the work room to the duct shaft not communicating with the chamber, and is exhausted through the duct shaft.

A device for medical room disinfection that reduces or eliminates hospital-acquired infections that comprises: an external housing; an upper intake of polluted air; a lower outlet of purified air; a blower; at least one filter; at least one UVC lamp; an ozoniser; at least an ionizer.

A germicidal disinfection apparatus, system and method. Embodiments of the present disclosure include an adaptive germicidal disinfection apparatus, system and method comprising one or more sensors communicably engaged with a controller being configured to control the operation of at least one UV-C emitter. The sensors may be configured to detect various signals from an interior environment and communicate such signals as inputs to the controller. The controller may be configured to process the inputs according to one or more data processing framework to assess and determine a variety of disease control risk factors and trigger conditions. The controller may be configured to configure one or more modes of operation for the at least one UV-C emitter according to an output of one or more data processing operations.

A sterilization particle includes a porous carrier material having at least one of the following: a microporous material, a mesoporous material, a macroporous material, or a combination thereof; and a sterilization material contained in pores of the porous carrier material or adsorbed on a surface of the porous carrier material. The sterilization material includes at least 4 weight percent of the sterilization particle. A sterilization device, a method for preparing a sterilization particle, and a method for sterilizing a space are also disclosed.

Electrical connectors and fixtures, and more particularly, electrical plug and socket combinations allowing quick connection and mounting of electrical fixtures are provided with a disinfection feature for disinfecting air and/or surfaces. Additionally, lighting fixtures include or are retrofitted to provide both lighting and disinfection functions. The disinfection feature can be provided by any suitable source of UV radiation, such as an LED array. The emitted UV radiation is UV-A or FAR UV-C so that disinfection can occur regardless of whether a human is exposed to the emitted UV radiation or the emitted UV radiation is UV-C so that disinfection should only occur if there is no human exposure to the emitted UV radiation. Some electrical connectors and fixture can provide both types of emitted UV radiation, which are selectively actuatable.

A device including an outer shell having a first longitudinal axis and a first arcuate shape. The outer shell is opaque to ultraviolet light and to visible light. The device also includes an inner shell having a second longitudinal axis. The inner shell is connected longitudinally to the outer shell along a first longitudinal length and a second longitudinal length. The inner shell has a second arcuate shape different than the first arcuate shape. A chamber is disposed between the outer shell and the inner shell. The chamber is defined by a difference between the first arcuate shape and the second arcuate shape. The device also includes an ultraviolet light source disposed along the second longitudinal axis.

Embodiments of a targeted surface disinfection system are disclosed. The system includes a set of one or more UV lamps, a high voltage power supply for driving the lamps, a mobile carriage including a chassis supporting the set, an articulated head assembly including at least one UV lamp from the set, a vacuum pump, and a suction hose extending between the vacuum pump and the head assembly for dissipating heat generated by the at least one UV lamp. The system also includes a pulse configuration control unit for configuring an output of the high voltage power supply for driving the set to emit a UV radiant energy upon a target surface requiring disinfection, where the set of one or more UV lamps emits the UV radiant energy at a rate of at least 20 pulses per second.

Embodiments of a targeted surface disinfection system are disclosed. The system includes a set of one or more UV lamps, a high voltage power supply for driving the lamps, a mobile carriage including a chassis supporting the set, an articulated head assembly including at least one UV lamp from the set, a vacuum pump, and a suction hose extending between the vacuum pump and the head assembly for dissipating heat generated by the at least one UV lamp. The system also includes a pulse configuration control unit for configuring an output of the high voltage power supply for driving the set to emit a UV radiant energy upon a target surface requiring disinfection, where the set of one or more UV lamps emits the UV radiant energy at a rate of at least 20 pulses per second.

A light fixture includes a housing forming a cavity to permit airflow therethrough. A filter is disposed within the airflow of the cavity. An ultraviolet light emitting diode is disposed within the cavity and is directed to concurrently treat the airflow and the filter to destroy biomaterial therein.