The present invention relates to a multifunctional robot system and method. The multifunctional robot system comprises an independently movable supply station and a plurality of robot units. The supply station comprises a power supply system and a supply station moving device; each robot unit is provided with a robot driving device, an operation execution device and a robot moving device; the supply station is connected with each robot unit respectively through a connecting cable. The multifunctional robot system is provided with the independent supply station, and the execution device of the robot is separated from the driving device thereof and a supply device; the supply station continuously provides raw materials and energy for the robot, the weight and size of the robot side are reduced, and working efficiency is improved.

A system for refilling, emptying and/or recharging of an autonomous floor cleaner includes a docking station adapted to be coupled with a household plumbing infrastructure. The docking station can be provided on a household appliance, which may be a toilet, a dishwasher, or another appliance coupled with the plumbing infrastructure.

A method for operating a cleaning system with a plurality of mobile cleaning devices and a base station for the cleaning devices as well as a base station for a plurality of mobile cleaning devices are proposed, wherein the cleaning devices can be emptied by the base station and/or filled with a cleaning agent by the base station simultaneously and/or according to a prioritization. In addition, a filter apparatus for a base station is proposed which has a plurality of connection openings in order to be able to empty a plurality of cleaning devices.

A system for refilling, emptying and/or recharging of an autonomous floor cleaner includes a docking station adapted to be coupled with a household plumbing infrastructure. The docking station can be provided on a household appliance, which may be a toilet, a dishwasher, or another appliance coupled with the plumbing infrastructure.

Provided are method and apparatus for acquiring water consumption of a robot vacuum cleaner, an electronic device and a non-transitory computer readable storage medium. Further, the method for acquiring water consumption of the robot vacuum cleaner includes: controlling the robot vacuum cleaner to acquire an image of ground to be cleaned, and acquiring the image of the ground to be cleaned; controlling the robot vacuum cleaner to detect a humidity of the ground to be cleaned, and acquiring humidity information of the ground to be cleaned; acquiring a target water consumption of the robot vacuum cleaner according to the image of the ground and the humidity information; and controlling the robot vacuum cleaner to clean the ground to be cleaned according to the target water consumption.

A system for autonomously cleaning a floor has a robot having a chassis. A clean water tank and a dirty water tank are disposed within the chassis. A valve in fluid communication with the dirty water tank receives dirty water from a cleaning surface during a cleaning operation. A docking station has a platform. A docking station drain communicates with the valve for receiving contents of the dirty water tank when the robot is in the docking station. A water source communicates with the clean water tank to fill the clean water tank when the robot is in the docking station. A charging structure charges the robot when the robot is in the docking station.

An integrated and modular air and lighting plenum that is the primary directional lighting mounting apparatus and laminar flow diffuser of an HVAC system in a healthcare setting. The plenum provides laminar air flow from the ceiling to the room in which it is located in accordance with HVAC requirements for healthcare environment settings, by using a plurality of cylindrical airflow outlets. The use of cylindrical airflow outlets promotes laminar airflow by reducing sharp boundaries that induce turbulence (e.g., the corners of rectangular or square outlets) and creates a highly sterile environment around the patient and staff in the operating room. The surgical lights used in the integrated air and lighting plenum allow the beam direction, spot size, focal point, brightness, and color temperature of the emitted light to be controlled.

A patient warming system for stabilizing and/or heating and cooling a patient includes a plurality of solid-surface sections arranged for attachment to a surgical table and a warming pad layer comprising a plurality of warming pads configured for removable connection to the plurality of solid-surface sections. At least one of the plurality of solid-surface sections includes a power connector for connection to an external power source. Each warming pad of the plurality of warming pads includes a foam insulation layer, a distributed heating element layer having a warming-pad power connection for connection to the power connector, an isothermal layer, and a flexible waterproof layer. Power supplied to the warming-pad power connection of the distributed heating element layer of the respective warming pad can be used to provide a user-selected uniform temperature over the surface of the flexible waterproof layer in order to prevent hot spots.

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.

The present disclosure relates to the field of cleaning robot technology, and in particular to a cleaning robot system. The cleaning robot system includes the base station and a cleaning robot. The base station is independent to the cleaning robot of the cleaning robot system. The base station includes a base station body and a mop member cleaning device arranged on the base station body. The mop member cleaning device is configured to clean a mop member of the cleaning robot. Based on the base station, the cleaning robot system is capable of automatically cleaning the mop member with no need for users to change or clean the mop member frequently, which is helpful to free consumers from house cleaning, thus relieving the burden on the consumers, and also helpful to clean the mop member in time so as to ensure a better effect in next cleaning.