A method for multipoint purification by a robotic air purifier, comprising the following steps: S1: establishing a coordinate map of an area to be purified; S2: the robotic air purifier moves within the area to be purified according to a preconfigured movement model, measuring air quality, remembering as level-1 pollution sources those points where a pollution value exceeds a preset threshold, and marking the coordinates of said points on the coordinate map; S3: when having completed its movement over the area to be purified, the robotic air purifier moves to each level-1 pollution source point and performs an initial purification process, while at the same time measuring air quality, continuing in this way until the air quality at all said level-1 pollution sources complies with requirements.

Described is related to a dual function robotic cleaning device for removing harmful chemical pollutants, viruses, unpleasant odors as well as particulates from indoor air in addition to cleaning dust and debris from the ground or floors. The device has a floor cleaning unit and an indoor air purification unit integrated in the same body which can operate automatically according to indoor air pollution levels as well as by a user's instructions. The air purification unit consists of a virus zapping filter for eliminating airborne viruses, a chemical and odor filter for removing toxic chemical pollutants and unpleasant odors, a particulate filter for trapping PM2.5, and a chemical sensor for detecting chemical pollutant levels in indoor air, which feeds pollution values to the control unit of the device to trigger the air cleaning operation.

An air conditioner is disclosed. The air conditioner comprises a storage, and a processor for identifying a target space on the basis of first gas sensing data, moving the air conditioner to the target space, acquiring information about a gas type on the basis of second gas sensing data sensed within the target space and reference data stored in the storage, and performing an air conditioning operation on the basis of the information about the gas type, wherein the gas sensing data is sensed by a sensor comprising a plurality of sensing modules that react to different gases.

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 conditioning robot according to an embodiment of the present disclosure includes: a main body having a suction hole and a discharge hole; a cooling cycle including a compressor, a condenser, an expansion mechanism, and an evaporator, which are disposed within the main body; a blower fan configured to blow air suctioned through the suction hole so that the air is heat-exchanged with the evaporator and discharged through the discharge hole; a heat storage tank configured to accommodate a heat storage material in which heat of the condenser is stored; a heat dissipation part configured to dissipate the heat of the heat storage material accommodated in the heat storage tank, the heat dissipation part thermally contacting a heat transfer terminal disposed outside the main body; and a driving part configured to allow the main body to move so that the heat dissipation part thermally contacts or is thermally separated from the heat transfer terminal.

A heating, ventilation, and/or air conditioning (HVAC) system includes a mobile air conditioning unit configured to separately dock with each docking station of a plurality of docking stations. The mobile air conditioning unit includes a refrigerant circuit configured to condition an airflow to produce a conditioned airflow and a transportation system configured to autonomously relocate the mobile air conditioning unit.

The present application provides an intelligent air purification robot with a mosquito-repelling function. In the present application, a robot body has an obstacle detection function and can make a turn automatically. That is, the robot body can automatically find a path after being placed in a room, and can purify air everywhere in the room. Dust-laden air enters a housing from an air inlet and is then treated by a plurality of modular units. Moreover, a UV lamp is further provided, so that air can be disinfected at a designated position.

A plurality of autonomous mobile robots includes a first mobile robot having a first module for transmitting and receiving an Ultra-Wideband (UWB) signal, and a second mobile robot having a second module for transmitting and receiving the UWB signal. The second mobile robot follows the first mobile robot using the UWB signal.

An embodiment of the invention may include a processor-implemented method and computer program product for temperature control. The embodiment may include performing, by at least one unmanned aerial vehicle, at least one local climate control action at a location based on data received from a wearable computing device of at least one individual.

A plurality of autonomous mobile robots includes a first mobile robot having a first module for transmitting and receiving an Ultra-Wideband (UWB) signal, and a second mobile robot having a second module for transmitting and receiving the UWB signal. The second mobile robot follows the first mobile robot using the UWB signal.