A cleaning system may include a vacuum cleaner and a docking station. The vacuum cleaner may include an air inlet, a suction motor having a suction motor inlet and a suction motor outlet, and a cleaner dust cup configured to transition between a collection position and an emptying position, the cleaner dust cup being upstream of the suction motor inlet when in the collection position and downstream of the suction motor outlet when in the emptying position. The docking station may include a base, a support extending from the base, a station dust cup removably coupled to the support, and a receptacle coupled to the support and configured to receive at least a portion of the vacuum cleaner, the cleaner dust cup being fluidly coupled to and upstream of the station dust cup when the vacuum cleaner is inserted in the receptacle.

A rechargeable vacuum cleaner assembly includes: a rechargeable vacuum cleaner provided with a first magnetic member (1011); and a charging stand (100) provided with a second magnetic member (1012), in which the first magnetic member (1011) is configured to cooperate with the second magnetic member (1012) through magnetic attraction so as to position the rechargeable vacuum cleaner to the charging stand (100).

A rechargeable vacuum cleaner assembly includes: a rechargeable vacuum cleaner provided with a first magnetic member (1011); and a charging stand (100) provided with a second magnetic member (1012), in which the first magnetic member (1011) is configured to cooperate with the second magnetic member (1012) through magnetic attraction so as to position the rechargeable vacuum cleaner to the charging stand (100).

A lid system for a wet-dry vacuum includes a lid shaped to cover an open end of a container and having a vacuum opening therethrough, and a hatch that engages the lid to cover and seal the vacuum opening when in a closed position and disengages from the lid in an open position to uncover the vacuum opening. A vacuum generator is mounted on the hatch, and a flanged filter is mounted on the lid and extends through the vacuum opening such that the flange supports the filter on the lid. When the hatch is in the closed position, the hatch compresses the flange against the lid to form an airtight seal between with the upper surface of the lid, and the vacuum generator communicates with the interior of the container. When the hatch is in the open position, the filter is insertable into and removable from the vacuum opening.

A cleaning tool for a vacuum cleaning accessory of a vacuum cleaning apparatus is disclosed. The cleaning tool may include a body having a suction opening for engaging with a surface to be cleaned. A cavity may be disposed within the body and fluidly connected with the suction opening. A flow channel may be disposed within the body downstream of the cavity. A brushroll may be rotatably mounted about a rotation axis in the cavity. An opening may extend through the body into the cavity for allowing atmospheric air to enter the cavity. The opening may be arranged above the brushroll with respect to the suction opening. Additionally or alternatively, the opening may be arranged in front of the brushroll with respect to the flow channel.

A pool-cleaning robot is provided, comprising: a robot body with a moving mechanism controlled to move the robot body forward or backward; wherein the robot body has a weight difference between its left and right sides; the moving mechanism includes a driver to drive the moving mechanism unilaterally; the robot body is provided with a fluid inlet-outlet, at least one first fluid inlet, and at least one first fluid outlet, which are communicated with each other. The fluid inlet-outlet is provided with a fluid driver that applies a suction force to the first fluid inlet or a discharge force to the first fluid outlet; a controller in the robot body, connected to and controlling the operation of the moving mechanism and the fluid driver; when the robot body is on a floor or walls of a pool, combinations of discharge forces, suction forces and weight differences steer the robot.

A pool-cleaning robot is provided, comprising: a robot body with a moving mechanism controlled to move the robot body forward or backward; wherein the robot body has a weight difference between its left and right sides; the moving mechanism includes a driver to drive the moving mechanism unilaterally; the robot body is provided with a fluid inlet-outlet, at least one first fluid inlet, and at least one first fluid outlet, which are communicated with each other. The fluid inlet-outlet is provided with a fluid driver that applies a suction force to the first fluid inlet or a discharge force to the first fluid outlet; a controller in the robot body, connected to and controlling the operation of the moving mechanism and the fluid driver; when the robot body is on a floor or walls of a pool, combinations of discharge forces, suction forces and weight differences steer the robot.

The vacuum cleaner includes: a vacuum cleaner main body including a suction device generating a suction force; a nozzle assembly connected with the main body and configured to suction air by the suction force of the suction device; a connector configured to connect the nozzle assembly with the main body and rotatably coupled to the nozzle assembly; and a locking unit which locks the main body to maintain a state in which the main body is erect and which unlocks the main body in the locked state by a rotation of the main body.

A multi-mode cleaning apparatus with suction may include a wand with a handle, a suction motor for providing suction, a bare floor unit configured to be movable by the wand and fluidly coupled to the suction motor, and a sweeper unit configured to be movable by the wand and fluidly coupled to the suction motor. The bare floor unit is configured for use in a suction only mode. The sweeper unit includes a rotatable brush roll and is configured for use in a brush roll only mode or a suction and brush roll mode.

A cleaning system may include a vacuum cleaner and a docking station. The vacuum cleaner may include an air inlet, a suction motor having a suction motor inlet and a suction motor outlet, and a cleaner dust cup configured to transition between a collection position and an emptying position, the cleaner dust cup being upstream of the suction motor inlet when in the collection position and downstream of the suction motor outlet when in the emptying position. The docking station may include a base, a support extending from the base, a station dust cup removably coupled to the support, and a receptacle coupled to the support and configured to receive at least a portion of the vacuum cleaner, the cleaner dust cup being fluidly coupled to and upstream of the station dust cup when the vacuum cleaner is inserted in the receptacle.