An autonomous floor cleaner can include a housing, a drive system for autonomously moving the housing over the surface to be cleaned, a controller for controlling the operation of the autonomous floor cleaner, a tank adapted to hold liquid, and a carry handle joined with the tank and/or the housing. The carry handle is movable between different positions, including a position in which the autonomous floor cleaner can be lifted via the carry handle while an inlet and/or outlet of the tank is blocked.

A cordless wet and dry stick vacuum cleaner system has a portable power module, which includes an airflow generator, a battery, and control circuitry. This may be used with either a wet dirt management system and a wet vacuum nozzle or it may be used with a dry dirt management system and a dry vacuum nozzle. The shared power module enables power savings, whereas the other parts remain optimized for their specific function.

The invention pertains to a system consisting of a first floor treatment apparatus that is exclusively guided manually within an environment by a user and a second floor treatment apparatus that is exclusively operated automatically, wherein the second floor treatment apparatus is designed for orienting and localizing itself within an environment. The first floor treatment apparatus is designed for detecting a movement path of the first floor treatment apparatus during a movement of the first floor treatment apparatus that is manually guided by a user, as well as for transmitting information on the detected movement path to the second floor treatment apparatus by means of wireless communication. The second floor treatment apparatus is designed for receiving the information and for autonomously traveling along the movement path within the environment based on the received information.

The present disclosure discloses a mobile robot and a control method thereof. More particularly, when a movement is detected in an area to be cleaned, a mobile robot learns whether the detected movement is a behavior pattern of causing a foreign material or not. The mobile robot performs a suitable cleaning when the movement of causing the foreign material is found or detected later.

Embodiments of the present disclosure provide a cleaning robot and a control method thereof. The cleaning robot includes a chassis; a drive system; an energy storage unit, supported by the chassis and includes at least one charging contact sheet, wherein the charging contact sheet protrudes from a plane of the chassis slightly, and the energy storage unit is configured to be charged according to a predetermined amount in a case that the robot is located at a charging station; and a control system, disposed on a main circuit board inside the cleaning robot and including a non-transitory memory and a processor, wherein the control system is configured to control the energy storage unit to charge according to the predetermined amount based on a to-be-cleaned area and a total power consumption factor.

A cleaning system includes a cleaning vehicle that cleans a predetermined travel route, and a control device. The cleaning vehicle includes a state detection device that detects a state of the travel route, and has a cleaning mode in which the cleaning is performed and a non-cleaning mode in which the cleaning is not performed. The control device executes inspection control for causing the state detection device to detect a state of a pre-set inspection region along the travel route while causing the cleaning vehicle to travel in the non-cleaning mode, specification control for specifying a cleaning required region, where the cleaning needs to be performed in the travel route, based on the state of the inspection region detected in the inspection control, and cleaning control for causing the cleaning vehicle to travel in the cleaning mode in the cleaning required region after the above-mentioned controls end.

A detecting device including an optical sensor includes: a cover member that is arranged at least partially around the optical sensor and is rotatable about a first rotation axis; and a rotation sensor configured to detect rotation of the cover member.

An autonomous cleaning robot includes a controller configured to execute instructions to perform one or more operations. The one or more operations includes operating a drive system to move the cleaning robot in a forward drive direction along a first obstacle surface with a side surface of the cleaning robot facing the first obstacle surface, then operating the drive system to turn the cleaning robot such that the side surface of the cleaning robot faces a second obstacle surface, then operating the drive system to move the cleaning robot in a rearward drive direction along the second obstacle surface, and then operating the drive system to move the cleaning robot in the forward drive direction along the second obstacle surface.

A robot maintenance station and a robot cleaning system. The robot maintenance station includes a dock base and a maintenance station body, the maintenance station body is configured on the dock base and provided with a suction unit, the suction unit is configured to provide suction power for sucking garbage. The maintenance station body is provided with a garbage receptacle and a suction tube, the suction tube is in flow communication with the suction unit and is configured to guide the garbage into the garbage receptacle, and the garbage receptacle is detachably mounted at a side wall of the maintenance station body. The embodiments realize automatic emptying of the dust box of the cleaning robot, thereby reducing user burden and improving user experience.

A mobile robot device and a method for controlling a mobile robot device to more accurately control positioning of the mobile robot device relative to a docking station. The mobile robot device obtains a first position relative to a docking station by scanning surroundings of the mobile robot device using a LiDAR sensor emitting a first frequency, moves the mobile robot device towards the charging station based on the first position, determines whether a distance to the charging station is within a first distance, controls the LiDAR sensor to scan the surroundings of the mobile robot device by changing a frequency of the LiDAR sensor to a second frequency less than the first frequency when the mobile robot device approaches within the first distance, and moves the mobile robot device towards the charging station based on the LiDAR sensor emitting the second frequency.