An integrated control system for controlling components of a setting of a healthcare environment, the integrated control system including one or more wireless computing devices; one or more displays; a plurality of components of the setting, wherein at least one component of the plurality of components is an ozone sterilization system, an integrated air and lighting plenum, a surgical lighting system, a pass-through logistics cabinet, or a floor sterilization robot; and a server. The server includes a connection for connecting to a remote healthcare environment information system, and a receiver and a transmitter for communicating data between the plurality of components of the setting, medical equipment connected to one of the plurality of components, the remote healthcare environment information system, the one or more wireless computing devices and the one or more displays.

Described herein are components, systems, and methods of use of an integrated sterilization system comprising a pass-through logistics cabinet, an ozone sterilization system, a floor sterilization robot, and systems for controlling such components. An integrated operating room sterilization system will allow mitigation or elimination of risks (e.g., infrastructural risks (e.g., OI risks), procedural risks (e.g., risk of infection and contamination) that are associated with a setting in a healthcare environment. The elimination of clutter, control of major components under a unified and intuitive user interface, and the logical elimination of potential accumulated risk events (e.g., OI risks) and procedural risks are deliberately addressed, in whole or in part, by the present disclosure. The present disclosure describes the following: a pass-through logistics cabinet, an ozone sterilization system, a floor sterilization robot, and systems for controlling such components.

Described herein are components, systems, and methods of use of an integrated sterilization system comprising a pass-through logistics cabinet, an ozone sterilization system, a floor sterilization robot, and systems for controlling such components. An integrated operating room sterilization system will allow mitigation or elimination of risks (e.g., infrastructural risks (e.g., OI risks), procedural risks (e.g., risk of infection and contamination) that are associated with a setting in a healthcare environment. The elimination of clutter, control of major components under a unified and intuitive user interface, and the logical elimination of potential accumulated risk events (e.g., OI risks) and procedural risks are deliberately addressed, in whole or in part, by the present disclosure. The present disclosure describes the following: a pass-through logistics cabinet, an ozone sterilization system, a floor sterilization robot, and systems for controlling such components.

To provide an electric cleaning apparatus including a vacuum cleaner that loads an appropriate amount of electrolyzed water and does not reduce convenience in terms of power consumption and lightness. An electric cleaning apparatus includes a vacuum cleaner and a station. The vacuum cleaner comprises: a first reservoir configured to store electrolyzed water; and a first cleaner configured to clean a surface to be cleaned by using the electrolyzed water supplied from the first reservoir. The station comprises: a second reservoir configured to store water; an electrolyzed-water generator that generates the electrolyzed water by electrolyzing the water; and a supply system configured to supply the first reservoir with the electrolyzed water generated with the electrolyzed-water generator when the vacuum cleaner is connected to the station.

Provided are a self-cleaning method of a self-moving cleaning robot and a self-moving cleaning robot which has both a working mode and a self-cleaning mode. When the self-moving cleaning robot needs to perform self-cleaning, the following steps are performed: controlling the robot to enter the self-cleaning mode; enabling the robot to start a self-cleaning action; and after a self-cleaning condition is satisfied, ending the self-cleaning mode. The present disclosure automatically clean part of the stains left at a rolling brush, a rolling brush cavity, a water suction port, a dust suction port and an air duct of the self-moving cleaning robot without changing an original working mode of the self-moving cleaning robot, and can prevent remaining pollutants from dropping onto a working surface to cause secondary pollution, is easy to operate and convenient to control, and can effectively realize a self-cleaning process of the self-moving cleaning robot.

A dock for a floor cleaner is provided. The dock includes a receiving unit for receiving the floor cleaner, and a reservoir for containing liquid. A nozzle is arranged to spray a floor cleaner received in the receiving unit with liquid from the reservoir such that an agitating cleaning effect is provided.

A docking station for removing wet and dry debris from a floor cleaner. The docking station includes a dry debris conduit for evacuating a debris from the floor cleaner and a wet debris conduit for evacuating liquid and wet debris from the floor cleaner. The liquid and wet debris may be collected from a pad cleaning cycle performed at the docking station. Methods for servicing or performing maintenance on a floor cleaner by a docking station are disclosed.

A mobile dock is disclosed and includes a receiving unit for receiving the floor cleaner. The paired device may be the floor cleaner, or a smart device of a user. The mobile dock follows a user, such that the dock is conveniently accessible during use of the floor cleaner.

A base station of a cleaning device and a cleaning system are provided. The base station of the cleaning device includes: a base station body having an accommodating chamber for accommodating the cleaning device and an opening for the cleaning device to enter or exit the accommodating chamber; and a water injection assembly including a movable base, and a movable plate, a lifting mechanism, and a water injection pipe that are disposed on the movable base. The water injection pipe is configured to inject water into the cleaning device. The lifting mechanism is configured to drive the water injection pipe to move. A first elastic member is disposed between the movable plate and a side wall of the accommodating chamber. The cleaning device is contacted with the movable plate during a water injection process of the water injection assembly.

A robot configured to perceive a model of an environment, including: a chassis; a set of wheels; a plurality of sensors; a processor; and memory storing instructions that when executed by the processor effectuates operations including: capturing a plurality of data while the robot moves within the environment; perceiving the model of the environment based on at least a portion of the plurality of data, the model being a top view of the environment; storing the model of the environment in a memory accessible to the processor; and transmitting the model of the environment and a status of the robot to an application of a smartphone previously paired with the robot.