The present disclosure relates to a method for controlling a plurality of moving robots, in which by dividing an area to be cleaned into a plurality of regions, and detecting sub-regions in the respective regions, the plurality of moving robots share information on the sub-region and the respective regions, and perform cleaning alternately to reduce the waste of cleaning time.

Some embodiments include a robot, including: a plurality of sensors; at least one encoder; a processor; a tangible, non-transitory, machine readable medium storing instructions that when executed by the processor effectuates operations including: measuring, with the at least one encoder, wheel rotation of at least one wheel; capturing, with an image sensor, images of an environment as the robot moves within the environment; identifying, with the processor, at least one characteristic of at least one object captured in the images of the environment; determining, with the processor, an object type of the at least one object based on characteristics of different types of objects stored in an object database; and instructing, with the processor, the robot to execute at least one action based on at least one of: the object type of the at least one object and the measured wheel rotation of the at least one wheel.

A cleaning system includes a cleaning vehicle that cleans a predetermined travel route, a maintenance facility provided at a specified position on the travel route and performs maintenance on the cleaning vehicle, and a control device that controls them. The control device executes interruption and maintenance control in response to a state of the cleaning vehicle satisfying a predetermined maintenance condition during execution of the cleaning by the cleaning vehicle. The interruption and maintenance control includes first control for interrupting the cleaning performed by the cleaning vehicle, causing the cleaning vehicle to move to the specified position, and causing the maintenance facility to perform the maintenance on the cleaning vehicle, and second control for causing, after the first control, the cleaning vehicle to move to an interruption position at which the cleaning was interrupted, and causing the cleaning vehicle to resume the cleaning from the interruption position.

A robotic device comprising: an energy storage device; and a controller configured to determine whether a quantity of energy stored in the energy storage device is below a predetermined energy level, wherein: the robotic device is configured to perform a cleaning task if the determined quantity of energy is not below the predetermined energy level; if the determined quantity of energy is below the predetermined energy level: the controller is configured to estimate a likelihood of the robotic device being capable of locating a recharging base station; and in dependence on the estimated likelihood, the robotic device is configured to seek the recharging base station or perform the cleaning task.

Disclosed is a cleaner. The cleaner includes a cleaner body, a suction nozzle configured to suck dust on a floor surface, and a suction hose configured to transfer the dust, transferred from the suction nozzle, to the cleaner body. The cleaner body includes a driving driver or motor moving the cleaner body, a depth sensor configured to obtain image information about an object near the cleaner body, and a processor configured to extract a foot sole region of a person, based on the obtained image information, obtain a moving point of the cleaner body, based on the extracted foot sole region, and control the driving driver to move the cleaner body to the obtained moving point.

Disclosed is a robot cleaner including a light source for irradiating light, a sensor for sensing that the light irradiated from the light source is reflected, and a controller that processes an image using the light sensed by the sensor to calculate a distance value of an individual location of the corresponding image, wherein it is determined that there is an obstacle when there is a dead zone in the image processed by the controller.

Industrial vacuum cleaner configured for servicing at least one construction tool, said vacuum cleaner comprising a vacuum inlet, wherein said vacuum cleaner further comprises a controller and connected to said controller a wireless transceiver, a memory, and at least one location and/or orientation sensor configured for detection of vacuum cleaner location and/or localization of other objects in relation to the vacuum cleaner and wherein the vacuum cleaner further comprises means for propulsion controlled by said controller.

A robotic cleaner may include a body having a top surface, a navigation sensor extending from the top surface of the body, a protective cover defining a sensor cavity, the navigation sensor being at least partially received within the sensor cavity, and a cover liquid diverter extending from an upper portion of the protective cover, the cover liquid diverter being flared in a direction of the body.

Disclosed herein is an air cleaner disposed in an indoor space. An air cleaner according to an embodiment includes a blowing device including a suction port and a discharge port, a fan motor configured to generate an air flow, a purifying unit installed inside the blowing device to purify air, a driving portion configured to move the air cleaner, a communication unit configured to communicate with a moving agent moving in the indoor space, and a processor configured to receive status information including at least one of air quality information and dust occurrence information collected by the moving agent, determine a specific zone in which air purification is to be performed using the status information collected by the moving agent, and perform air purification in the specific zone.

A vacuuming faucet assembly includes a faucet that is integrated into a counter top. A pair of vacuum units is each integrated into the faucet and each of the vacuum units includes a suction port that is in fluid communication with a vacuum source. The suction port on each of the vacuum units is extendable away from a respective vacuum unit for suctionally removing water from the counter top to dry the counter top. A plurality of motion sensors is each integrated into a respective one of the faucet and a respective one of the pair of vacuum units to sense motion proximate the respective faucet and the respective pair of vacuum units. Additionally, respective ones of the motion sensors turns on the respective faucet of the respective vacuum unit when the respective motion sensor senses motion.