Provided is a robot cleaner including a main body for forming an exterior of the robot cleaner, a driver for moving the main body, a cleaning module housing coupled to the main body, and a mopping unit accommodated in a space defined in the cleaning module housing to mop a traveling face, wherein the mopping unit includes a body disposed in the cleaning module housing, a plurality of mopping rollers arranged on the body, and a mop disposed to surround the body and the plurality of mopping rollers and in a surface contact with the traveling face. An area in contact with the traveling face is increased, so that a cleaning efficiency may be maximized.

A cleaning robot is provided. The cleaning robot includes a body, a light detection and ranging (LiDAR) module having a LiDAR sensor rotatably supported by the body, a light-emitting display module mounted on the LiDAR module, wherein the light-emitting display module is configured to display an image based on an afterimage effect according to a rotation of the LiDAR module.

A cleaning device includes: a housing; a drive device for automatically moving the cleaning device in a movement direction; and a wet-cleaning module accommodated in the housing, the wet-cleaning module including a moveable cleaning element for the wet cleaning of surfaces to be cleaned. The cleaning element is belt-shaped. In an embodiment, the wet-cleaning module has three positions for the belt-shaped cleaning element: a cleaning position, in which the cleaning element is configured to contact a surface to be cleaned with a cleaning surface; a parking position, in which the cleaning element is at a distance from the surface to be cleaned; and a regeneration position located between the cleaning position and the parking position, or a regeneration position located in the parking position in which the cleaning element is regeneratable. The wet-cleaning module has a transport mechanism for moving the cleaning element into its cleaning, parking, and regeneration positions.

The present disclosure provides cleaning robot, including a cleaning agent mopping device (1), a cleaning agent absorbing device (2), a water wiping (3) and washing device (4), and a water absorbing device arranged in turn along a moving direction of the cleaning robot. Each time when the cleaning robot of the present disclosure works to clean the to-be-cleaned surface, the cleaning robot can perform the four steps including cleaning agent mopping, cleaning agent absorbing, water wiping and washing, and water absorbing, thus, both hydrolysable and non-hydrolysable stains can be effectively cleaned by the cleaning robot. Thus, the cleaning robot is very practical, easy to operate, and simple to use.

The present disclosure discloses an automated cleaning robot which includes a robot body capable of realizing automatic walking and a mop mechanism provided at a rear end of the robot body. The mop mechanism includes a mount support rotatably connected to the robot body, a rotation component received in and rotatably connected to the mount support, a crawler-type wiping cloth sleeving outside the rotation component, and a lifting mechanism being in transmission connection with the mount support, for driving a rear end of the mount support to ascend or descend relative to a front end of the mount support.

A cleaning equipment includes a first take-up reel, a first supply reel, a frame, a first cleaning film, and a transmission assembly. The frame includes an inner space accommodating the first take-up reel and the first supply reel side by side and an outer surface having at least one gap communicating with the inner space. The first cleaning film has a supply part on the first supply reel, a take-up part on the first take-up reel, and a middle part at least partially covering the outer surface of the frame. Two ends of the middle part enter the inner space through the at least one gap and are connected to the supply part and the take-up part, respectively. The transmission assembly is coupled to the first supply reel and the first take-up reel and drives at least one of the first supply reel and the first take-up reel to rotate.

The present invention relates to a wiping mop (10) with a housing (20), wherein an anchoring mechanism (11) for a handle (12) for guiding the wiping mop (10) is attached to the upper side of the housing. A wiping band (30) which is closed in itself is guided partially around and partially through the housing (20). On entry into the housing (20) the wiping band (30) runs through a mechanical dirt separator as well as a first (80) and a second (70) tank to be filled with wiping liquids in each case, whereby the wiping band (30) is cleaned of dirt particles taken up during use and is moistened for further wiping. Before leaving the second tank (80) the wiping band (30) is wrung out by cheeks of an outlet slot which are displaceable manually relative to one another.

A surface cleanup machine that can clean up grout off a surface or a floor is described.

The present disclosure discloses an automated floor cleaning apparatus, has an automatic cleaning robot and a washing base; the rear end of the robot body of the automatic cleaning robot is provided with a mop mechanism, the mop mechanism comprises a rotation component rotatably connected to the robot body and a crawler-type wiping cloth sleeving outside and rotating along with the rotation component. The invention provides can automatically and effectively removes dirt attached to the crawler-type wiping cloth, avoiding artificial detaching and then cleaning the wiping cloth stained with dirt, automatically performing washing operation, greatly alleviating operation burden of a user, and having a good floor sweeping effect.

The present invention relates to a wiping mop (10) with a housing (20), wherein an anchoring mechanism (11) for a handle (12) for guiding the wiping mop (10) is attached to the upper side of the housing.

A wiping band (30) which is closed in itself is guided partially around and partially through the housing (20). On entry into the housing (20) the wiping band (30) runs through a mechanical dirt separator as well as a first (80) and a second (70) tank to be filled with wiping liquids in each case, whereby the wiping band (30) is cleaned of dirt particles taken up during use and is moistened for further wiping. Before leaving the second tank (80) the wiping band (30) is wrung out by cheeks of an outlet slot which are displaceable manually relative to one another.