The present disclosure provides a surface cleaning apparatus that includes a housing including a base adapted for movement across a surface to be cleaned, a fluid delivery system, and a recovery system. The surface cleaning apparatus can be configured to clean multiple surfaces, including hard and soft surfaces, and for different cleaning modes, including wet cleaning, dry vacuum cleaning, and self-cleaning. Methods for self-cleaning a surface cleaning apparatus are also provided.

A portable surface cleaning apparatus for a floor surface includes a main housing assembly adapted to be hand carried by a user, the main housing assembly carrying a fluid delivery system adapted for storing cleaning fluid and delivering the cleaning fluid to the surface to be cleaned, and a fluid recovery system adapted for removing the cleaning fluid and debris from the surface to be cleaned and storing the cleaning fluid and debris that was recovered, the main housing assembly comprising a base housing, a supply tank received on the main housing assembly, a recovery tank received on the main housing assembly separately from the supply tank.

A floor washing machine includes a handle assembly; a control unit provided at the handle assembly; a power supply unit electrically connected to the control unit; a rod assembly connected to the handle assembly; a base assembly connected to a lower portion of the rod assembly; a sweeping/scrubbing assembly provided at the base assembly and having a motor controlled by the control unit and a scrubbing roller to be driven into forward or reverse rotation by the motor; and a water supply assembly having a water outlet pipe, wherein the water outlet pipe has a water outlet opening and can be rotated in order to point the water outlet opening to a forward-of-roller direction or a rearward-of-roller direction of the sweeping/scrubbing assembly.

A driving mechanism for an autonomous planar surface cleaning robot is disclosed. The driving mechanism includes a first transmission component and a second transmission component spaced apart in parallel relationship relative to the first transmission component. Each of the first and second transmission components defines first and second ends and first and second sides, wherein the first sides face each other and the second sides face away from each other in a direction transverse from the direction of motion and the first and second ends are oppositely spaced along the direction of motion. Each of the first and second transmission components are independently controllable by a control unit of the autonomous planar surface cleaning robot.

Disclosed are a robot cleaner capable of controlling a water pump of a robot cleaner by a user input through an external control device, a robot cleaning system having the same, and a control method of the robot cleaning system. According to the present invention, user convenience is increased since the amount of water supplied to the mop of the robot cleaner can be controlled according to a cleaning environment, cleaning efficiency is improved by controlling the water pump to quickly wet the mop of the robot cleaner at the beginning of a cleaning operation, and the robot cleaner can be hygienically managed since a user controls the water pump to discharge residual water inside the robot cleaner.

The present invention relates to a robot cleaner, a control system of a robot cleaner and a control method of a robot cleaner, and the invention includes a robot cleaner that stores a map including information on a drivable area of a cleaning area and drives in the cleaning area and a terminal that inputs a cleaning command to the robot cleaner, the terminal setting a virtual designated area on the map in response to a user input, the robot cleaner moving to the designated area and driving within the designated area when the designated area is set from the terminal, and thus, the invention has the effect of intensively cleaning the designated area arbitrarily designated by a user.

A handheld extractor that includes a housing, a supply tank adjacent a first side of the housing, and a recovery tank adjacent a second side of the housing. A cleaning chamber is in the third side of the housing. A fluid flow path is between the supply tank and the cleaning chamber. The cleaning chamber receives a suction nozzle and a suction source provides suction through a hose and the second fluid flow path to extract the cleaning fluid from the supply tank, along the fluid flow path into the cleaning chamber, through the hose and into the recovery tank to flush the cleaning fluid through the hose to clean the hose when the suction nozzle is received in the cleaning chamber.

A method of controlling a shoe care device is provided. The method includes obtaining contamination level information of shoes by using at least one sensor, performing a shoe care operation in one operation mode among a plurality of operation modes, determining whether to transmit a cleaning request to at least one robotic vacuum cleaner, based on at least one of the contamination level information of shoes or the operation mode being performed, and transmitting the cleaning request to the at least one robotic vacuum cleaner, based on a determination to transmit the cleaning request.

A surface maintenance machine includes a body, a surface maintenance tool coupled to the body, processing circuitry supported at the body, and a light projection mechanism supported at the body and coupled to the processing circuitry. The light projection mechanism includes a light housing, a light emitting element within the light housing, and a projection lens that is configured to focus light emanating from the light emitting element. The light projection mechanism is configured to project light onto a ceiling surface that is above a floor surface along which the surface maintenance machine is configured to perform a surface maintenance task using the surface maintenance tool.

An extraction cleaner includes a portable extractor and a base adapted to be moved to perform a cleaning operation on a floor surface when the portable extractor is operably mounted to the base. The portable extractor includes a recovery tank assembly provided on the housing adjacent to the recovery tank assembly.