An illustrative expendable or reconstructable ozone generator cartridge for an aqueous ozone delivery device, for example, for antimicrobial sanitizing and/or medical treatment, includes a housing for a water ozonating manifold, at least one ozone generating cell coupled to the manifold, and optionally a data logging and authentication feature. Advantageously, a water inlet, an aqueous ozone outlet, and an electrical connector of the ozone generator cartridge are simultaneously pluggable into and unpluggable from a docking station of the aqueous ozone delivery device, for example, a hand or implement washing and sanitizing device or a medical treatment device.

Provided are a toothbrush sterilizing assembly and an electric toothbrush. The toothbrush sterilizing assembly includes a sterilizing shell, a sterilizing cover, a sterilizing element, a control module and a power supply module. The sterilizing shell has a cylindrical shape and is sleeved outside an electric toothbrush. The sterilizing cover is detachably connected to one end of the sterilizing shell and is capable of covering the one end of the sterilizing shell. The sterilizing element is disposed on an inner wall of the one end of the sterilizing shell. The control module is connected to the sterilizing element and configured to control the sterilizing element to start to sterilize a brush head of the electric toothbrush. The power supply module is electrically connected to the control module.

An apparatus is used for cleaning and drying applicator tools, such as brushes, cosmetic applicators, or cosmetic tools. The apparatus according to various embodiments includes an applicator tool holder configured to hold multiple applicators of various sizes with the applicator heads facing down. The applicator tool cleaning apparatus has a cleaning chamber that can dispense liquid to saturate the applicator heads and contact the applicator heads with a textured surface to dislodge collected materials on the applicator heads and a drying chamber where drying mechanisms blow air or dissipate heat at the applicator heads until dried. The applicator tool holder may be moved vertically between the cleaning chamber and the drying chamber via a motor and drive mechanism. Alternatively, the applicator tool holder may be flipped such that the applicator heads are facing upwards and aligned with the drying mechanisms.

A device for cleaning items comprises an enclosure defining a wash chamber, a rotor positioned within the wash chamber and selectively rotatable about an axle, a motor for selectively rotating the axle, a dispenser, and a drain. The rotor comprises a plurality of holders spaced about the axle and adapted to selectively receive and hold a respective item to be cleaned. The dispenser at least one liquid input and at least one liquid output and is positioned such that the at least one liquid output directs cleaning fluid at one of the items to clean material out of the cavities. The drain is for draining the cleaning fluid out of the chamber. The rotor is selectively rotatable at a predefined rotational speed for a predefined amount of time to expel cleaning fluid from the cavities of each item to be cleaned.

An information processing apparatus includes a sound information generation unit configured to generate sound information in which a physiological sound of a body is extracted from an acquired sound, a sound direction detection unit configured to detect a direction of the physiological sound of the body based on the sound information, a facial state detection unit configured to detect a state of a face existing in the direction of the physiological sound of the body detected by the sound direction detection unit, from an image captured and generated by an imaging unit, and a contamination information generation unit configured to generate contamination information in which a predetermined area according to the state of the face is set as a contaminated area, based on the state of the face detected by the facial state detection unit.

A mountable virtual reality station and system include a unit body having a plurality of walls including a back wall and a front wall. The back wall is configured for connection with a structure, such as a wall of a room or booth. The unit further includes a touch screen and headset mounting display arranged on the front wall, and a power source connected with the unit body. Preferably, the unit includes a system indicator display, wherein the system indicators are at least one of a power indicator, a Wi-Fi indicator, and a Bluetooth indicator. The unit also preferably includes a virtual reality headset tether connected with the unit body configured for connection with a virtual reality headset.

A mobile disinfection device (200) includes a disinfection chamber (203) coupled to a propulsion system (228) configured for moving along a surface (236) to be disinfected. The disinfection chamber defines a closed distal end (205), an open proximal end (206) and a surrounding wall (207) impervious to the radiation and having opposing front and rear portions and opposing side portions, respective proximal front, rear and side edges of which are propelled by the propulsion system close to the surface to be disinfected. A radiation source (260) is mounted inside the disinfection chamber for irradiating the surface through the open proximal end. The propulsion system includes a peripheral seal (304) surrounding a proximal edge of the wall and configured to obstruct radiation that might otherwise escape from inside the disinfection chamber.

A dryer including: a drum; a duct connected to the drum; a compressor connected to an evaporator and a condenser provided inside the duct; a heater provided inside the duct; a fan provided inside the duct; a motor to rotate the fan; and a controller configured to perform a first operation of operating the compressor, the heater, and the motor based on no object being inside the drum, and a second operation of operating the heater and the motor without operating the compressor. The dryer may sterilize the inside of the dryer, particularly, a flow path through which humid air passes.

Embodiments of the invention are directed to apparatuses and methods for cleaning and disinfecting probes. A cleaner is utilized to remove foreign materials (e.g., bioburden, soil, and other like material) from the probe after it is removed from the patient by soaking and/or flushing the foreign materials from the probe. The cleaner may be an enzymatic detergent that has bacteriostatic properties to inhibit bacterial growth within the apparatus. The multiple enzymes in the cleaner attack the foreign material, and include low-foam properties for effective recirculation across cycles within the cleaning step. The probe is rinsed after the cleaning step, and after rinsing a disinfectant process is applied to the probe. The disinfectant soaks and/or flushes the probe for a specified amount of time across cycles of recirculation to disinfect the surface of the probe, and afterwards the probe is rinsed thoroughly to remove the disinfectant from the probe.

An apparatus includes a first production line configured to generate aqueous ozone with a first ozone concentration. The apparatus also includes an additional production line configured to generate aqueous ozone with an additional ozone concentration. The first production line and the additional production line include a flow switch, where fluid is configured to flow through the flow switch. The first production line and the additional production line include an ozone generator, where the ozone generator is configured to generate ozone when the fluid flows through the flow switch. The first production line and the additional production line include a fitting coupled to the flow switch and the ozone generator, where the fitting is configured to combine the generated ozone and the fluid to generate the aqueous ozone. The first production line is configured to generate aqueous ozone independently from the additional production line.