An intelligent air purifier includes a machine body, a mobile unit, at least one sensor, and a control unit. The machine body has an air inlet, a consumable substance, and an air outlet. The air is sucked from the air inlet, purified by the consumable substance, and discharged from the air outlet. The mobile unit is mounted to the machine body. The sensor is disposed on the machine body for detecting an air quality index of the air in a room. The control unit is communicated with the mobile unit and the senor through electrical signals. The control unit is preset with a pollution value. When the air quality index of the air at a position in the room is greater than the pollution value, the control unit controls the mobile unit to move the machine body to the position to purify the air.

A method is disclosed that includes continuously obtaining air purity and floor particle data from one or more sensors and/or one or more cameras of a robotic device among a fleet of robotic devices; determining whether air impurities around the robotic device exceed an air purity threshold based on air purity feedback from the one or more sensors of the robotic device; based on the determination whether air impurities around the robotic device exceed the air purity threshold, modifying an air purification mode of the robotic device; determining whether floor particles around the robotic device exceed a floor particle threshold based on floor particle feedback from the one or more sensors of the robotic device; and based on the determination whether floor particles around the robotic device exceed the floor particle threshold, modifying a floor cleaning mode of the robotic device.

An air humidifying device and a moving method thereof, an air humidifying system and a control method thereof, and a monitoring system are disclosed. The moving method includes: determining a target region to be humidified, the target region being any one of N to-be-humidified regions, and N being an integer greater than or equal to 2; determining movement trace information of the air humidifying device moving towards the target region; moving to the target region according to the movement trace information; and humidifying the target region. The method is used in a humidifying process of the air humidifying device, which not only expands the scope of air humidification, but also makes the air humidifying device move flexibly.

Despite otherwise uncomfortable conditions in a surrounding environment, a customizable microenvironment can be created around a user to maintain a comfortable temperature and/or humidity level using a comfort unit. For example, the environment may be an office building where conditions are out of the comfortable range to save on energy or for other reasons, a factory/shop environment that is poorly conditioned, or an outdoor location with little to no conditioning. A sensing unit can monitor biometric and environmental data and can determine a comfort level of the user. The comfort unit can then dynamically respond to the determined comfort level and adjust the microenvironment to improve the user's comfort level. The comfort unit can follow the user as the user moves within the macro-environment, or can otherwise move within the macro-environment to achieve certain functions, such as recharging or spatial shifting of thermal load within the overall macro-environment.

An autonomous robotic device capable of vacuum cleaning and purifying air includes an autonomous robotic vacuum cleaner for moving autonomously and vacuum cleaning, and an air purifier. The autonomous robotic vacuum cleaner has a power supply and a top surface provided with a plurality of positioning members. The air purifier has an air inlet, an air outlet, and a plurality of matching members at the bottom thereof. The air purifier is detachably disposed on the autonomous robotic vacuum cleaner in a way that the matching members are in contact with the positioning members to create a positioning relationship for positioning the air purifier on the autonomous robotic vacuum cleaner, and an electrical connection to enable the air purifier to receive electric power from the power supply of the autonomous robotic vacuum cleaner.

An integrated autonomous air purification device for taking in polluted air, carrying it through the inside of the purification device where it passes through a set of filtering elements (1) that trap the dust particles contained in the air; ultraviolet-light lamps (2) that transform NO.sub.X and CO gases in the air into harmless compounds; an activated carbon filter (4) that traps and eliminates the volatile organic compounds and inorganic acidic gases; second filtering elements (5) that carry out a second filtering; and an extraction hood (6) configured to direct the air coming out of the second filtering elements (5) to at least one nozzle (7) that expels the air to the outside of the purification device.

A mobile apparatus includes a mobile portion, a cabin housing that is mounted to the mobile portion and defines a first space and a second space, and an air-conditioning apparatus installed in the second space and configured to cool or heat the first space, where a compressor, a condenser, an expansion device, and an evaporator are modularized in the air-conditioning apparatus.

An air purification method includes the steps of acquiring air quality data within the air purifying area, determining whether the air quality data falls within a predetermined threshold range, determining an operation mode of the air purifier by a ratio between an area size of the air purifying area and a coverage area of the air purifier when the acquired air quality data is not fall within the threshold range, and controlling the air purifier at the operation mode thereof to purify air within the air purifying area. The operation mode of the air purifier is determined according to a ratio between an area size of the air purifying area and a coverage area of the air purifier.

An autonomous robotic device capable of vacuum cleaning and purifying air includes an autonomous robotic vacuum cleaner for moving autonomously and vacuum cleaning, and an air purifier. The autonomous robotic vacuum cleaner has a power supply and a top surface provided with a plurality of positioning members. The air purifier has an air inlet, an air outlet, and a plurality of matching members at the bottom thereof. The air purifier is detachably disposed on the autonomous robotic vacuum cleaner in a way that the matching members are in contact with the positioning members to create a positioning relationship for positioning the air purifier on the autonomous robotic vacuum cleaner, and an electrical connection to enable the air purifier to receive electric power from the power supply of the autonomous robotic vacuum cleaner.

A smart artificial intelligence based mobile robot having an air purification, humidification, dehumidification, and ultraviolet cleaning-based system to remove pathogens is disclosed. The robot also acts as an emergency alert system for break-ins and human fall detection using AI algorithm. The mobile robot operates and navigates intelligently using real time data collected from the environment through various sensors and input devices. An object detection module may use inputs from the camera to recognize people, pets, and others by pre-trained machine learning data set. The mobile purification, humidity management and sanitizing robot includes a ball bearing for balance and a motor controller, which drives two motors and wheels. The central controller of the smart mobile robot system has memory and processor to handle navigation, communication, notifications, and air handling system through real time data collection.