A docking method executable by a mobile device is provided. The docking method includes obtaining a stored target location of a docking station, and navigating to the target location. The docking method also includes: during the navigation and/or at the target location, based on a determination that a guidance signal is not detected, performing a regional search. The docking method also includes: during the navigation, or at the target location, or during the regional search, based on a determination that the guidance signal is detected, moving, under the guidance of the guidance signal, to the docking station. Performing the regional search includes determining a basic search zone, searching for the guidance signal while moving along boundaries of the basic search zone, and based on a determination that the guidance signal has not been detected when a termination condition is satisfied, terminating the regional search.

A cleaner includes a body forming an external appearance, and a spin-mop cleaning module configured to support the body and including at least one spin-mop provided so as to come into contact with a floor while rotating in a clockwise direction or in a counterclockwise direction when viewed from an upper side. The inclination angle of a lower surface of the spin mop is changeable relative to a horizontal plane.

A mobile floor cleaning robot includes a body defining a forward drive direction, a drive system, a cleaning system, and a controller. The cleaning system includes a pad holder, a reservoir, a sprayer, and a cleaning system. The pad holder has a bottom surface for receiving a cleaning pad. The reservoir holds a volume of fluid, and the sprayer sprays the fluid forward the pad holder. The controller is in communication with the drive and cleaning systems. The controller executes a cleaning routine that includes driving in the forward direction a first distance to a first location, then driving in a reverse drive direction a second distance to a second location. From the second location, the robot sprays fluid in the forward drive direction but rearward the first location. The robot then drives in alternating forward and reverse drive directions while smearing the cleaning pad along the floor surface.

A down-pressure mopping type sweeping robot includes a sweeper body and a sweeper water tank. The sweeper body includes a battery pack and a mounting portion formed at a bottom of the sweeper body. A protrusion portion is formed in the mounting portion. The sweeper water tank is detachably installed in the mounting portion for wetting the ground to be cleaned during a mopping process. A bottom of the sweeper water tank is fixed with a rag through a sticky-and-hook strap. Both sides of an inside of the sweeper body are fixed with down-pressure assemblies by bolts. The down-pressure assembly includes a down-pressure protrusion capable of elastically protruding into the mounting portion. The down-pressure protrusions are elastically pressed downwardly on a top of the sweeper water tank so that the rag can be stably pressed against the ground to be cleaned.

A recharging method for a mobile robot includes: receiving a recharging signal transmitted by a charging station when the mobile robot is in a recharging working state; moving forward toward the charging station by the mobile robot according to the recharging signal; performing a U-turn operation by the mobile robot when the mobile robot determines that a front end of the mobile robot is aligned with a position of the charging station; and moving backward along the direction approaching the charging station to move to the position where the pole piece of the charging station is located by the mobile robot.

A surface cleaning apparatus having an upright assembly, a power source, and a coiled electrical cable. The upright assembly including a frame and a telescoping handle at last partially extending from the frame and movable between an extended position and a contracted position. The coiled electrical cable being provided within a portion of the telescoping handle and configured to uncoil or coil when the telescoping handle is moved between the extended position and the contracted position.

A cell module assembly includes multiple lithium-ion battery cells connected in parallel and an electronic controller. The electronic controller is programmed to receive useful life data for a useful life indicator of the battery cells, save the life data to memory to create a life data history, determine a life measurement based on the life data history, compare the life measurement to a first end of life threshold, determine if the life measurement has met the first end of life threshold, provide a first end of life output indicating that the life measurement has met the first end of life threshold, compare the life measurement to a second end of life threshold, determine if the life measurement has met the second end of life threshold, and provide a second end of life output indicating that the life measurement has met the second end of life threshold.

In some examples, a method for docking an autonomous mobile robot includes: determining a first effective region, wherein the first effective region is defined by a boundary, and wherein the autonomous mobile robot is located in the first effective region; determining an optimal point from a plurality of candidate points on the boundary of the first effective region, wherein each candidate point defines a respective second effective region centering on the candidate point and overlapping with the first effective region to form a respective overlapping region, wherein the respective overlapping region associated with the optimal point is smallest among the respective overlapping regions associated with the plurality of candidate points; controlling the autonomous mobile robot to move to the optimal point; and repeating the above steps in one or more iterations until the autonomous mobile robot is within a preset distance from a charging station.

A charging pile for sweeping robot including a main body, a storage component, a charging head, a charging cable, and a circuit board. The main body is provided with a first slot. The storage component, provided with a charging interface and an avoidance slot. The charging pile for sweeping robot includes a first mounting post movably connected to the main body. The charging cable is partly wound on the first mounting post, one end of which is detachably connected to the charging interface, and the other surrounds the first mounting post and penetrates through the avoidance slot and is fixedly connected to the charging head. The charging interface is electrically connected to the main body, so the charging cable can be wound on the first mounting post and contained in the first slot, prevented from being scattered on ground, and making the charging pile more beautiful when in use.

The present disclosure relates to a battery powered floor cleaner (10). The floor cleaner (10) is operable in various modes based on the capacity of a battery pack (22), such as a normal power mode (40) and a low power mode (42).