Provided are a cleaning robot and a cleaning cloth bracket for the cleaning robot, including a cleaning cloth bracket, where the cleaning cloth bracket includes a main body, a soft member and a raised portion, a cleaning cloth is provided under the cleaning cloth bracket, the cleaning cloth bracket is floatingly disposed at a bottom of a base of the cleaning robot, the raised portion is provided at a front end of the main body through the soft member, and the raised portion is in contact with the bottom of the base. According to the present disclosure, by increasing the height of the raised portion and providing the soft member between the raised portion and the main body of the cleaning cloth bracket, the range of application of the cleaning robot is improved, the cleaning robot is allowed to overcome higher obstacles, and the cleaning efficiency is improved.

A mobile robot includes a body, a driving system connected to the body and configured to drive the mobile robot move on ground, a detecting module supported by the body and a controller received in the body. The detecting module includes a light source emitting light towards the ground, and a light sensor configured to obtain characteristic information and a shutter value of an image of the ground. The controller is configured to adjust the intensity of the light source according to the characteristic information of the image and monitor conditions of the ground according to the shutter value, which can accurately detect conditions of the ground and prevent misjudgment of the mobile robot.

A robotic cleaner may include a chassis, an agitator assembly configured to engage a surface to be cleaned, and a lift mechanism moveably coupling the agitator assembly to the chassis. The lift mechanism may include a biasing mechanism. The biasing mechanism may be configured to generate a biasing force that urges the agitator assembly in a direction away from the surface to be cleaned. The biasing force may be insufficient to lift the agitator assembly from the surface to be cleaned.

A cleaner includes a body forming an external appearance, a rotating plate provided at a lower side of the body, a mop unit coupled to a lower side of the rotating plate so as to be in contact with a floor, a spin shaft connected to an upper side of the rotating plate so as to rotate the rotating plate, a water supply reservoir configured to surround a periphery of the spin shaft and spaced apart from the spin shaft so as to define a water supply space, and a water supply module configured to supply water to the water supply space. The rotating plate forms a water supply hole configured to interconnect the water supply space and the lower side of the rotating plate.

A cleaning assembly and a cleaning apparatus are provided. The cleaning assembly includes a fixing mechanism, a lifting shaft, a moving member, a first drive mechanism and a cleaning module. The lifting shaft penetrates through the fixing mechanism and is configured to slide along an axial direction of the lifting shaft relative to the fixing mechanism. One end of the lifting shaft is connected to the cleaning module, and the other end is connected to the moving member. The moving member is configured to cause the lifting shaft to slide along the axial direction of the lifting shaft. The first drive mechanism is connected to the moving member by a transmission device and is configured to cause the moving member to move in a reciprocating motion.

A robot cleaner includes a rolling cleaning module including a rolling member configured to rotate clockwise or counterclockwise when viewed from a left side while in contact with a floor, a sensor unit, and a controller. The controller is configured to determine a change in position of the robot cleaner and a change in load current of a motor connected to the rolling member based on data detected by the sensor unit, and determine that a specific area of the floor is a contaminated area when there is a change in the position and a change in the load current.

The present application provides an autonomous cleaning robot. The autonomous cleaning robot may include a main body and a cleaning assembly mounted on the main body. The cleaning assembly may include a first cleaning subassembly. The first cleaning subassembly is removable mounted on the main body. The first cleaning subassembly can be loaded into or unloaded from the main body in a forward and backward direction. The first cleaning subassembly of the autonomous cleaning robot is easy to be assembled.

The present application provides a liquid container and an autonomous cleaning robot. The liquid container may include a container case and a water outlet filter. The container case may define a water outlet (321) thereon and a liquid accommodating room therein. The water outlet communicates with the liquid accommodating room in the container case. The water outlet filter is mounted on the water outlet. The water outlet filter is configured to regulate the rate of the water outlet. The rate of the liquid container is better.

A surface processing device for processing surface areas with obstacles, comprising a chassis, surface processing means and first and second sensory means, characterized in that it further comprises a movable assembly, adapted to affect exposure of the surface processing means to surface area, wherein the movable assembly is adapted to move, based on information from the first and the second sensory means, at least between a first position and a second position with respect to the chassis, wherein in the second position the surface processing means have different exposure to surface area than in the first position.

A method for adjusting a position of suction lips of a floor cleaning machine relative to a floor to be cleaned is proposed, wherein a first suction lip and at least one second suction lip located at a distance therefrom, which are arranged on a suction beam, contact the floor, a fan device generates a suction flow which subjects a space between the first suction lip and the second suction lip to a negative pressure, a negative pressure is detected, and the suction flow is adjusted such that the negative pressure lies at a set value or in a set value range, so that an angle of incidence of the first suction lip and the second suction lip on the floor lies at a set value or in a set value range.