An extraction cleaner includes a steam delivery system, a liquid delivery system, and a recovery system, and includes multiple cleaning modes, including a first cleaning mode in which components of the steam delivery system, liquid delivery system, and recovery system are active, a second cleaning mode in which components of the delivery system and recovery system are active, and a third cleaning mode in which components of the steam delivery system are active. Methods for operating an extraction cleaner are also provided.

Display of a wet cleaning routine of an autonomous floor cleaning robot is provided. Estimated wetness of areas of the floor can be tracked and displayed to the user so they can avoid walking on those areas of the floor until sufficiently dried. The areas of the map that that are still wet from cleaning can be displayed and transition to a different type of indicia over time as the floor dries. The wet floor status can be tracked with a timer by comparing elapsed time since the autonomous floor cleaner traversed the subject region and dispensed cleaning solution with an estimated drying time for cleaning solution on the floor. The estimated drying time can be based upon the flow rate of the autonomous floor cleaner.

The disclosure discloses a debris collecting base station, a cleaning robot and a cleaning system. The debris collecting base station cooperates with the cleaning robot. The cleaning robot has a debris outlet for discharging debris. The debris collecting base station includes a base, a debris collecting device, a first communication component and a microcontroller. The base has a debris intake passageway. One end of the debris intake passageway pneumatically interfaces with the debris outlet, the debris collecting device is mounted on the base and is communicated with the end of the debris intake passageway away from the debris outlet. The microcontroller is electrically connected to the first communication component and the debris collecting device, which controls the first communication component to send and receive interactive signals with the cleaning robot and controls working modes of the debris collecting base station based on the interactive signals.

A burnisher for cleaning and polishing floors is provided. The burnisher includes at least one electric motor powered by at least one battery. The at least one battery can be provided as one or more lithium ion batteries. The burnisher is configured to rotate a burnisher pad at various speeds, as selected by the operator. The burnisher includes a control area including various input and output devices that can control the burnisher and provide information regarding operational parameters of the burnisher, respectively. The control area further includes a touchscreen display that allows the operator to direct the operation of the burnisher.

The present disclosure provides an electric steam control method, a system thereof, and a steam cleaner. The method includes: obtaining current water temperature data of a hot water tank and a current power supply mode; determining whether a temperature corresponding to the current water temperature data is within a preset temperature range; and if the temperature is within the preset temperature range, entering a heat preservation mode, else detecting whether AC power is currently available; if the AC power is available, performing power supply using the AC power, else generating a water temperature alarm signal; and in the heat preservation mode, detecting whether a working state is currently in place; if the working state is in place, detecting whether the AC power is currently available and generating a steam ejection signal, and performing power supply by using the AC or DC power, else maintaining the heat preservation mode.

The present invention relates to a floor surfacing machine (1) comprising a frame (2) that is carried by a first wheel (3) and a second wheel (4). The floor surfacing machine (1) further comprises a first motor (6), a handle arrangement (7), at least one planetary head (15) that is rotatably mounted to the frame (2) and at least one satellite surfacing head (19, 20, 21) that is rotatably mounted to the planetary head (15), where the first motor (6) is arranged to propel the planetary head (15). The floor surfacing machine (1) comprises a first control unit (10), and a remote control panel (11) which in turn comprises a second control unit (12) that is arranged to communicate with the first control unit (10). The floor surfacing machine (1) also comprises a second motor (22) that is arranged to propel the satellite surfacing heads (19, 20, 21) such that the planetary head (15) and the satellite surfacing heads (19, 20, 21) are independently operable.

The invention relates to a surface cleaning machine, including a cleaning head having at least one cleaning roller unit which is driven for rotary movement, and a tank device for dirty fluid, wherein a probe device is provided for determining a degree of fill of the tank device for dirty fluid.

A device (1) for automatically performing an activity, in particular for cleaning dirty surfaces, having at least one sensor (3) and at least one drive element (4). The drive element (4) divides the device (1) into a rear region (11) and a front region (12), on the basis of the intended direction of movement (B). The sensor (3) is a mechanical sensor which is arranged in the front region (12) of the device (1) and is used to determine, by contact with the floor, a change in the height of the floor.

A method and system for path sweeping of a cleaning robot, and a chip are disclosed. The method includes: detecting, in real time, a collision state of the cleaning robot in a turning process during S-shaped sweeping in a current cleaning area; and then controlling an -shaped path of the cleaning robot according to the collision state, so that the cleaning robot achieves sweeping an area between an arc-shaped edge corresponding to a turning part of the -shaped path, and a corner of the current cleaning area.

A surface cleaning apparatus adapted for movement across a surface to be cleaned. The surface cleaning apparatus can dock within a storage tray and charge a power supply. Electrical contacts on the surface cleaning apparatus and the storage tray can be shielded when the surface cleaning apparatus is not docked within the storage tray. Furthermore, the storage tray can include a reservoir for a self-cleaning mode.