A docking station for a robotic cleaner may include a base, the base including a support and a suction housing, a docking station suction inlet defined in the suction housing, the docking station suction inlet being configured to fluidly couple to the robotic cleaner, and a docking station suction motor, wherein the docking station suction motor is activated after the robotic cleaner is determined to be docked with the docking station and in response to a triggering event.

Devices for collecting patient excretions utilize existing suction sources and facilitate the cleaning of bedding and/or a patient. Patient excretion collection devices comprise a collection reservoir and a collection wand which are attached to an existing source of suction.

Embodiments of the present invention provide a wireless dust collection system capable of integration into an existing or new dust collection configuration and capable of wireless activation in response to the activation of a connected workshop implement or in response to a user input through a user interface. The wireless collection system has at least one gate mechanism assembly, at least one wireless trigger assembly, an intermediary hub, a collector, a collector bin, and at least one wireless control interface.

There is provided a robot cleaner having an improved dust-collecting capability and an improved suction force and capable of being manufactured in a small size. The robot cleaner includes a main body comprising a fan motor and having a suction port provided in one side thereof; a plurality of cyclone units configured to separate foreign substances in air suctioned through the suction port; and a plurality of suction flow paths connecting the plurality of cyclone units and the suction port.

Disclosed is a vacuum cleaner that opens or closes a hole formed in a suction portion according to a state of a surface to be cleaned, thereby efficiently cleaning. A vacuum cleaner includes a suction portion configured to suck foreign materials on a surface to be cleaned. The suction portion includes a case having an air hole formed in a flow path, a frame configured to be accommodated in the case and open or close the air hole, and a button configured to be mounted on the case and be operated to move the frame.

A brushless vacuum device may include a vacuum head having a bottom side, a first and second exterior wall, a front end, and a back end. The first exterior wall and second exterior wall may be positioned on the bottom side and may be coupled together at the front end. A suction aperture may be positioned proximate to the front end. A first plurality of jets may extend along the first exterior wall between the suction aperture and the back end. A second plurality of jets may extend along the second exterior wall between the suction aperture and the back end. A suction conduit may be in communication with the suction aperture and may generate negative air pressure in the suction aperture. A pressure conduit may generate a positive air pressure in the first plurality and second plurality of jets. Air exiting the jets may be collected by the suction aperture.

A vacuum cleaner basically includes a base, a motor, first and second inlets, and first and second flexible members. The motor is configured to create flow through a suction path. The first inlet and the second inlet are disposed in the base in fluid communication with the suction path. The first flexible member and the second flexible member are connected to the base to cover the second inlet. The first and second flexible members are movable between first positions in which the second inlet is substantially covered to substantially prevent fluid from flowing through the second inlet and second positions in which fluid is allowed to flow through the second inlet.

A vacuum cleaner basically includes a base, a motor, first and second inlets, and first and second flexible members. The motor is configured to create flow through a suction path. The first inlet and the second inlet are disposed in the base in fluid communication with the suction path. The first flexible member and the second flexible member are connected to the base to cover the second inlet. The first and second flexible members are movable between first positions in which the second inlet is substantially covered to substantially prevent fluid from flowing through the second inlet and second positions in which fluid is allowed to flow through the second inlet.

Apparatus and method for receiving and holding debris in a collection chamber of a vacuum cleaner. A cleaning head is coupled to a body of the vacuum cleaner via one or more suspension elements that comply to horizontal oscillations of the cleaning head imparted by an offset bearing of a vertical gear drive driven by a motor mounted to the body. A vacuum source draws air in from a suction nozzle at a forward underside portion of the cleaning head adjacent to a cleaning pad, and the air travels through an air filter disposed between the vacuum source and the collection chamber. In some embodiments, the air filter comprises one or more pleats adjacent to the vacuum source.

A cleaner includes a dust separation unit which separates dust from sucked air; a dust container which stores the dust separated by the dust separation unit; a first suction port through which an external air is sucked into the dust separation unit; a second suction port through which the external air is sucked into the dust separation unit; a discharge port through which air inside the dust separation unit is discharged; and a flow path blocking member which selectively covers the first suction port and the second suction port.