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.

A water-dispensing device includes a cold water tank and a fill valve. The tank is in selective fluid communication with a water intake via the fill valve. The device further includes a cold dispensing valve, a spigot in selective fluid communication with the tank via the cold dispensing valve, an ozone generator in fluid communication with the tank, and a drip tray positioned beneath the spigot. The drip tray is in fluid communication with a drain via a drain hose. A controller is configured to perform a cleaning operation by: (i) activating the ozone generator to ozonate water stored in the tank, (ii) opening the cold dispensing valve to empty the tank by dispensing the ozonated water from the tank through the spigot and into the drip tray, and (iii) upon determining the tank is empty, opening the fill valve to refill the tank.

The disclosure is based on a medical imaging apparatus with a scanner, a patient support apparatus and a housing, which is arranged on the scanner and/or on the patient support apparatus, wherein the housing comprises at least one functional housing shell, wherein the at least one functional housing shell comprises at least one sensor element for detection of a hygiene status on the at least one functional housing shell, at least one output element, which is embodied for a visual display of the hygiene status, and at least one cleaning element for cleaning a surface of the at least one functional housing shell.

To sterilize a sterilization filter unit with heated steam, minimize the heat load on the sterilization filter unit and extend the service life of the sterilization filter unit.

Heated steam is supplied to a sterilization filter unit that sterilizes supplied air, the temperature of the heated steam discharged from the sterilization filter unit is measured at predetermined time intervals, the F value is calculated from the measured temperature, and sterilization of the sterilization filter unit is ended when the F value reaches a target value.

Mobile apparatuses and methods are provided that utilize visual marker detection (VMD) systems to determine and/or verify one or more locations in an area/room at which a mobile apparatus has been arranged and/or to determine and/or verify a mobile apparatus has been suitably positioned at a preset location in an area/room. Moreover, mobile apparatuses and methods are provided that utilize VMD systems to affect the operation of a mobile apparatus, particularly when and/or what manner the apparatus is operated. Furthermore, mobile apparatuses and methods are provided that utilize VMD systems to determine whether a mobile apparatus has moved to other locations in an area/room in a particular time frame, such as during operation of the apparatus. In addition, mobile apparatuses and methods are provided that utilize VMD systems to convey information that is specific to the location of the apparatus.

An illustrative control system for use with a replaceable ozone generator cartridge for use with an aqueous ozone delivery device, for example, for sanitizing objects, including hands, hands and forearms, feet, other tissue, instruments, or other object sanitizing. One embodiment of the control system calculates and transmits usage data to a memory device of the ozone generator cartridge, and also includes various sensors and drivers for controlling an aqueous ozone concentration. The control system also provides other data logging, error detection, and identity verification of the replaceable ozone generator cartridge.

An ozone generator for producing ozone water for the sanitation and disinfection of an ice maker includes cathode plates and anode plates that are arranged alternatively in an electrolysis chamber. The cathode plates and the anode plates are connected to a cathode wire and an anode wire of a cable. A wiring chamber is provided with a temperature sensor extending into the electrolysis chamber and connected with a temperature sensor wire of the cable. The cable is connected to a control circuit. The ozone generator is submerged in the ice-making water of the ice-making water tank. The temperature sensor of the ozone generator submerged in the ice-making water is configured to sense temperature changes. When the ice maker is activated, the temperature of the ice-making water in the ice-making water tank will drop. When the temperature drops to the set temperature, the ozone generator is activated once to produce ozone gas. The ozone gas is dissolved in the ice-making water to generate ozone water. The ozone water is used to sanitize the ice-making loop process of the ice maker. The ozone generator has simple structure, low cost and good effect.

Technologies (e.g., devices, systems and methods) for sanitizing mist humidifiers are described. In some embodiments, the technologies include a sanitization gas system and a connector unit. The connector unit is configured to install into an opening in the mist humidifier that is used in operation to release mist for humidification purposes. The connector unit includes an inlet passageway for supplying sanitizing gas (e.g., ozone) into the humidifier, and an exhaust system for removing sanitizing gas from the reservoir.

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 treatment manifold providing parallel and operably fixed water pathways through ozone generating cells coupled to the manifold, and optionally a data logging and authentication feature.

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 and aqueous ozone outlet of the ozone generator cartridge is 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.