The present disclosure provides an ultraviolet (UV) sterilization apparatus that is capable of changing an emission mode and/or an emission angle. The UV sterilization apparatus includes a sterilization unit configured to be movable to a predetermined position and including a UV emitter, and a driving unit configured to move the sterilization unit.

The present disclosure provides an ultraviolet (UV) sterilization apparatus that has improved heat dissipation performance and is capable of being changed in position. The UV sterilization apparatus includes a sterilization unit configured to be movable to a predetermined position and including a UV emitter, a driving unit configured to move the sterilization unit, and a cover having a structure accommodating the sterilization unit and allowing the inside of the cover to communicate with the outside. A heat sink is provided in the cover in order to dissipate heat from the sterilization unit.

An HVAC duct ozone generator includes at least two ozone generation plate stacks, where each plate stack includes at least two independently electrically addressable plate groupings, where a primary plate grouping includes fewer ozone generation plates than a secondary plate grouping. Thus, the generator includes at least four independent ozone generation control channels to energize the primary and secondary plate groupings of each of the at least two plate stacks. The number of plates in a plate grouping may optionally be altered to reduce the ozone generation capacity of the primary plate grouping in relation to the secondary plate grouping through the movement of resistive collars between the stacked ozone generation plates.

An irradiation method includes irradiating an environment with light using one or more one ceiling-mounted light sources, where each ceiling-mounted light source has an optical axis oriented vertically downward, and wherein each ceiling-mounted light source emits a light distribution having more angle-integrated intensity in a higher angular range relative to the optical axis of the ceiling-mounted light source than in a lower angular range relative to the optical axis of the ceiling-mounted light source. A ceiling-mounted light source may include a support structure, one or more light emitters disposed on a surface of the support structure, and a reflector with a funnel-shaped reflective surface facing the support structure and expanding with increasing distance from the support structure along the optical axis. The light emitters may be ultraviolet (UV) light emitters whereby the light source is a UV ceiling-mounted light source.

A sanitation device includes a housing with a channel extending into the housing and a plurality of openings in the channel. A plurality of light emitting diodes emit light through the openings in the channel. A shield is coupled to the housing and a motion sensor emits and detect light through the shield when activated, such that the shield narrows a field of view of the motion sensor. The sanitation device is positioned near a common touch point with the motion sensor determining when an object is near, and has moved away from, the touch point. The plurality of light emitting diodes are activated to clean the touch point after the object moves away. The sanitation device may further include a status indicator light to provide information regarding the current state of operation of the sanitation device.

A method for sterilizing closure elements (3) for packaging containers (1), wherein the closure elements (3) are collected individually by a holding mechanism (25) in the region of a sterile chamber (12) and are placed onto an opening (4) of a filled packaging container (1) and connected to the latter, and wherein the closure elements (3), while being conveyed inside the sterile chamber (12), are treated by means of at least one sterilizing medium (6, 7, 52) during a sterilizing process.

Several embodiments relating to ultraviolet face shield systems and methods of use are provided herein. Such face shield systems feature an ultraviolet light source capable of inactivating, destroying, or killing germs, bacteria, viruses, or other pathogens such as human coronavirus COVID-19, and protecting individual(s) from infection.

A personal, portable, handheld UV light sanitizer (20) having a tubular housing (22) with a UV light source (32) for uniformly radiating a user's hand through a light transmittable outer wall (24) of the housing having a girth and length that enables substantially the entire the exterior surface of the outer wall to be covered by a user's hand when fully grasping the outer wall. A rearward annular wall (41) reduces any rearward light leakage and provides a bearing surface against which the edge of the user's hand may rest to prevent slippage. An annular forward wall (40) reduce forward light leakage and mounts actuation switches (36, 56), remote sensors (58, 60), a status indicator light (61) and an alarm speaker (59). When the skin surface sanitization mode switch (36) is actuated, skin sanitizing UV light radiation (42) radiates the inside of the user's hand for a preselected time period, unless there have previously been an excessive number of past hand sanitization cycles or too little time has passed since the last hand sanitization cycle (FIG. 9). Once energization, it is automatically deenergized after a preselected maximum time period (FIG. 9). Mounted to the front of the forward annular wall is another UV light source (51) that radiates UV light to suspect target surfaces spaced from the user's hand. A range finder (58) helps the user to hold the surface UV light source at the right distance from the target surface for effective sanitization, and energization is immediately terminated in response to an infrared sensor detecting that the surface UV light source is directed at a person's skin.

A disinfection system that provides homogenous UV light output. The system can utilize a sensor system to detect proper use provide user feedback on safety and functional operation. By tracking cumulative dosage of low energy UV-C the system can disinfect without violating safety exposure standards The system can automatically provide a disinfection dose according to the type and length of body contact device the disinfection device is mounted to, while tracking operational details. The system can include crypto security that enables a safer ecosystem and HIPAA compliant statistic sharing of operational parameters.

A sterilization and air purification control system and a mounting structure of a waste disposer include a bottom mounting housing and a disposer main machine and a sterilization module. The sterilization module includes an ozone generator driver, a negative oxygen ion generator and an exhaust mechanism. The bottom mounting housing is an accommodating housing and is detachably mounted at a bottom portion of the disposer main machine, an outer edge of the bottom mounting housing is provided with a light strip, the exhaust mechanism is fixedly connected to an inside of one side surface of the bottom mounting housing, and the exhaust mechanism communicates with inner and outer sides of the bottom mounting housing.