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 method for bringing cleaning robots into and out of a trolley, and cleaning system, in which each cleaning robot is automatically brought into the trolley individually and the cleaning robots are automatically brought out of the trolley in an order depending on the cleaning effort assigned to them or in a sequence specified by a user of the trolley. A cleaning system comprises a trolley and a multiplicity of cleaning robots configured to carry out the method.

A method for emptying cleaning robots and cleaning system, having a dirt collection unit and a suction interface using a trolley, configured to store the plurality of cleaning robots outside their cleaning phase in which they carry out cleaning tasks, and which has a suction system with a foldable suction platform, a suction opening, a dirt container, and a blower. The method includes the steps of unfolding the suction platform of the trolley, if it is folded, so that it is arranged on a substrate on which the trolley stands in an operational set-up position, arranging one of the cleaning robots on the unfolded suction platform, aligning the suction interface to the suction opening, and activating the blower in order to empty the cleaning robot arranged and aligned on the suction platform so that dirt is transported from the dirt collection unit into the dirt container.

The present disclosure provides a charging mount and a vacuum cleaner assembly including the charging mount and a vacuum cleaner. The support member is provided with the curved plate clamped by the claw of the fastening head, achieving a quick fixing of the vacuum cleaner to the charging mount. Once the fastening head is engaged with the curved plate, the first electrical contact can be accurately contact the second electrical contact to ensure a stable electrical connection, resulting in stable charging. The first baseplate is provided with a plurality of securing columns for fixing and mounting spare accessories, resulting in convenience for arrangement. The seating groove and the limiting plate of the second baseplate as well as the limiting block of the first baseplate contribute to secure and limit the position of the brush head portion, resulting a stable placement of the vacuum cleaner on the charging mount.

The present application discloses dust boxes, dust box assemblies and cleaning devices, wherein the dust box assembly includes a dust box and at least two fans. The dust box is formed with a holding cavity, a dust suction port and at least two air outlets, the dust suction port is connected to the holding cavity, the at least two air outlets are connected to the holding cavity. At least two fans are provided corresponding to at least two air outlets for creating an airflow that passes through the dust suction port, the holding chamber and the air outlet in sequence.

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.

A vacuum cleaner attachment generally includes a cleaning element that floats relative to a suction conduit of the vacuum cleaner attachment. The cleaning element is supported on a support structure that is movably coupled to a housing and is biased towards a floor, for example, as a result of the weight of the cleaning element support structure. The cleaning element may be permanently attached to the support structure or may be a removable or disposable pad or sheet attached to the support structure. The floating cleaning element may be supported between the suction conduit and one or more wheels of the vacuum cleaner attachment. The vacuum cleaner attachment may be removably attached to a vacuum cleaner, for example, to be used interchangeably with other surface cleaning heads.

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.

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.