A cleaning wheel structure, which mainly comprises a cleaning unit, a universal joint and an elastic element, wherein the cleaning unit comprises a plurality of clamping jaws disposed around the circumference of the shaft thereof, and each of the clamping jaws has a positioning groove, the universal joint is disposed between the plurality of clamping jaws, the elastic element is disposed between the universal joint and the cleaning unit, wherein the outer surface of the universal joint is convexly provided with a positioning portion for embedding with the positioning grooves, with the above structure, when the cleaning unit is stuck and cannot be driven to rotate by the universal joint, the positioning portion repeatedly pushes each of clamping jaws outwardly to rotate and to be embedded in the next positioning groove, so that the universal joint no longer drives the cleaning unit.

A robot cleaner according to an embodiment of the present invention comprises: a travelling part for moving a body; a memory for storing travel state information of the traveling part, which is recorded while a cleaning operation is performed on the basis of a first map; and a control part for discriminately detecting a first area and a second area divided from a plurality of cleaning areas corresponding to the first map, on the basis of the stored travel state information. Moreover, the control part may generate a second map by removing one of the first area and the second area from the first map, and then control the travelling part to perform a cleaning operation in a changed cleaning mode on the basis of the generated second map.

An autonomous floor cleaner includes a base that is movable over a surface to be cleaned, a collection chamber associated with the base, and a rotating top mounted coupled with the base for rotation relative to the base, where the top carries at least one sweeping element for sweeping dirt on the surface to be cleaned toward the collection chamber.

An autonomous floor cleaner includes a base that is movable over a surface to be cleaned, a collection chamber associated with the base, and a rotating top mounted coupled with the base for rotation relative to the base, where the top carries at least one sweeping element for sweeping dirt on the surface to be cleaned toward the collection chamber.

A cleaning robot and a method of controlling the same, the cleaning robot performing docking by detecting light emitted from a docking station using a Lidar sensor or a light receiving element separately provided on a printed circuit board (PCB) of the Lidar sensor, and performing docking based on the number of light emitting elements of the docking station identified according to the detected light are provided. The cleaning robot includes a main body, a drive unit configured to move the main body, a Lidar sensor including a Lidar optical transmitter, a Lidar optical receiver, and the PCB to which the Lidar optical transmitter and the Lidar optical receiver are fixed and provided to be rotatable, a docking optical receiver fixed to the PCB and configured to receive light emitted from the docking optical transmitter of the docking station, and at least one processor is configured to control the drive unit to be docked on the docking station based on light received by the docking optical receiver.

A cleaning robot and a method of controlling the same, the cleaning robot performing docking by detecting light emitted from a docking station using a Lidar sensor or a light receiving element separately provided on a printed circuit board (PCB) of the Lidar sensor, and performing docking based on the number of light emitting elements of the docking station identified according to the detected light are provided. The cleaning robot includes a main body, a drive unit configured to move the main body, a Lidar sensor including a Lidar optical transmitter, a Lidar optical receiver, and the PCB to which the Lidar optical transmitter and the Lidar optical receiver are fixed and provided to be rotatable, a docking optical receiver fixed to the PCB and configured to receive light emitted from the docking optical transmitter of the docking station, and at least one processor is configured to control the drive unit to be docked on the docking station based on light received by the docking optical receiver.

The present disclosure relates to a fixed universal vehicle mounted sweeper assembly. In accordance with one embodiment of the present invention, the sweeper assembly includes a plurality of brush strips, wherein the brush strips are positioned in a series of rows, such rows spaced apart in substantially parallel arrangement. Each of the plurality of brush strips is mounted to an underside of the assembly via a plurality of receiving channels. Each such cavity is adapted for affixing brush strips to the sweeper assembly. The sweeper assembly is modular, such that the components of such assembly can be packaged in a standard utility skid, and assembled in such a way that the structural integrity of the completed sweeper assembly is maintained.

A method of controlling an automatic cleaner in which the automatic cleaner is moved with a side brush assembly in a first operation type, a corner is determined during the movement of the automatic cleaner, the first operation type of the side brush assembly is changed to a second operation type to clean the corner when the corner is determined, whether the corner is cleaned is determined, and the second operation type of the side brush assembly is returned to the first operation type when the corner is cleaned.

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 ground; an in-position sensor disposed in a recess of chassis in which the fluid storage apparatus is mounted and configured to detect whether the fluid storage apparatus is in position and report an in-position state signal of the fluid storage apparatus to a control system; and the control system carried on the chassis and configured to plan a cleaning path according to in-position state signal of the fluid storage apparatus and control fluid applicator to distribute the cleaning fluid according to the cleaning path

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 ground; an in-position sensor disposed in a recess of chassis in which the fluid storage apparatus is mounted and configured to detect whether the fluid storage apparatus is in position and report an in-position state signal of the fluid storage apparatus to a control system; and the control system carried on the chassis and configured to plan a cleaning path according to in-position state signal of the fluid storage apparatus and control fluid applicator to distribute the cleaning fluid according to the cleaning path