A docking station for a mobile cleaning robot can include a base and a canister. The base can be configured to receive at least a portion of the mobile cleaning robot thereon. The base can include an electrical power interface configured to provide electrical power to the mobile cleaning robot. The canister can be connected to the base and can be located at least partially above the base. The canister can include a debris bin to receive debris from the mobile cleaning robot.

A robot cleaner comprising: a cleaner body including a controller, the cleaner body having a dust container accommodation part formed therein; a wheel unit mounted in the cleaner body, the wheel unit of which driving is controlled by the controller; and a dust container detachably coupled to the dust container accommodation part, wherein a first opening and a second opening are disposed at the same height in an inner wall of the dust container accommodation part, wherein the dust container includes: an entrance and an exit, disposed side by side along the circumference of the dust container, the entrance and the exit, respectively communicating with the first opening and the second opening when the dust container is accommodated in the dust container accommodation part; and a flow separating part extending downwardly inclined along the inner circumference of the dust container.

A trolley and method for loading and unloading cleaning robots into a trolley, including for storing, emptying and supplying energy to cleaning robots. The trolley includes an energy supply unit, storage compartments, each storage compartment having a charging contact which is designed to be contacted with a cleaning robot arranged in the corresponding storage compartment to supply the cleaning robot with energy, transport wheels configured to move the trolley over a substrate, a suction system having a foldable suction platform configured to empty one of the cleaning robots arranged on the suction platform, a lift system with a foldable receiving element configured to transport the cleaning robots individually by way of the receiving element in its unfolded state to the storage compartments and away from the storage compartments, and at least one door element configured to close or expose the foldable receiving element and the foldable suction platform.

An embodiment of the present disclosure provides a cleaning robot and a control method thereof. The cleaning robot includes: a chassis; a fluid applicator, carried on the chassis and configured to distribute a cleaning fluid on at least part of a cleaning width; a fluid storage apparatus, detachably connected to the chassis, wherein the fluid storage apparatus is in communication with the fluid applicator and configured to apply the cleaning fluid distributed by the fluid applicator to a floor; and a control unit, carried on the chassis and configured to control the fluid applicator to stop distributing the cleaning fluid in a case that a to-be-cleaned area of the floor reaches a preset value.

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 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.

A charging pile for sweeping robot including a main body, a storage component, a charging head, a charging cable, and a circuit board. The main body is provided with a first slot. The storage component, provided with a charging interface and an avoidance slot. The charging pile for sweeping robot includes a first mounting post movably connected to the main body. The charging cable is partly wound on the first mounting post, one end of which is detachably connected to the charging interface, and the other surrounds the first mounting post and penetrates through the avoidance slot and is fixedly connected to the charging head. The charging interface is electrically connected to the main body, so the charging cable can be wound on the first mounting post and contained in the first slot, prevented from being scattered on ground, and making the charging pile more beautiful when in use.

A docking station for a robotic vacuum cleaner has a pneumatic transfer mechanism that is used to direct air to the robotic vacuum cleaner to thereby transfer dirt from the robotic vacuum cleaner to a docking station.

A cleaning device having an electrical interface for interacting with an electrical counter-interface and a base station to charge the cleaning device. The cleaning device being configured to move autonomously in a processing environment, to carry out cleaning tasks, and to move into a service position with a base station. The cleaning device determines a range of service functions offered by a base station. When the cleaning device is in the service position, at least one measured value of a voltage or measured value of a voltage curve at the electrical interface provides a means of identification. This identification is used to determine the range of service functions at the base station or to identify a communication interface for use in determining the range of service functions by a data processing device. A cleaning system, a procedure, and a computer program product associated with the cleaning device is provided.

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.