A household appliance has a device housing, a blower arranged in the device housing, an outlet opening formed in the flow direction behind the blower in the device housing, and a flow channel. Soundwaves are generated by the blower, and produce resonances characterized by standing waves, which form between opposing inner walls of the flow channel. A sound reducing wall is positioned in the flow channel, the wall plane of which is oriented parallel to a primary flow direction of the air flow guided in the flow channel. The sound reducing wall is positioned in the flow channel so that a maximum for a fast amplitude of a sound particle velocity of the air flow guided in the flow channel lies in the wall plane of the sound reducing wall. The soundwaves form while interspersing the sound reducing wall between the opposing inner walls of the flow channel.

A stick vacuum cleaner having a handheld vacuum cleaner adapted to be docked to a stick. When the handheld vacuum cleaner is docked to the stick an air path is formed connecting an air outlet of the handheld vacuum cleaner with an air outlet provided in the stick. A noise absorption unit is provided in the air path or outside the air outlet from the stick.

A sweeping robot, comprising a bottom shell, a face shell forming an accommodation chamber together with the bottom shell, and a lower cover, an upper cover, a sealing intermediate cover, a fan unit, and a motor which are disposed in the accommodation chamber, wherein the motor is fixed at the lower cover; the fan unit is mounted on an output shaft of the motor, and is located on the lower cover; the sealing intermediate cover covers the lower cover; the lower cover is provided with an air inlet; the sealing intermediate cover and the lower cover together limit the fan unit inside; the upper cover and the sealing intermediate cover form therebetween an air outtake passage in communication with the fan unit; and the bottom shell and the face shell are provided therebetween with an exhaust passage in communication with the air outtake passage.

A cleaner reduces noise. The cleaner includes a motor, a fan including a number Z of blades and rotatable at a rotational speed N, indicating revolutions per minute, about a rotation axis by the motor, a cover having an inlet located frontward from the fan, and a number V of ribs located in the inlet. The ribs extend in a radial direction from the rotation axis and are arranged in a circumferential direction about the rotation axis. The fan is rotatable to produce noise having a frequency f.sub.NZ of 20,000 Hz or higher, and f.sub.NZ=(m−k×V)×N/60 and m=n×Z+k×V, where n is an order, m is an integer, and k is an integer.

A hand vacuum cleaner has an information display device provided on a rear wall of the rear end of the hand vacuum cleaner.

A vacuum cleaner system comprising a motor-impeller assembly, a power source, and a hose. The motor-impeller assembly is configured to generate fluid flow, the fluid flow passing through a hose inlet. The power source is configured to supply power to the motor-impeller assembly. The hose includes a proximal hose end configured to be coupled to the hose inlet, a distal hose end spaced from the proximal hose end, and a hose body. The hose body is coupled to the proximal hose end and the distal hose end. The hose body has an inner surface through which fluid flow passes, and an outer surface open to the surroundings of the hose. The hose further includes a layer of anti-static material applied to either the inner surface of the hose body or the outer surface of the hose body.

A cyclonic, dust-collecting unit includes: one or more air swirling members, which swirl(s) air; a dust cap, into which air that has passed through the swirling member(s) flows; and a filter unit, through which air that flows out of the dust cap passes. The filter unit includes: a prefilter; a sound-absorbing member, through which air that has passed through the prefilter flows; and a post filter, through which air that has passed through the sound-absorbing member flows.

A housing (e.g. a vacuum cleaner) includes a fan aggregate having a part in which a fan is mounted, and a motor mounted at a first side of the part. An elastic suspension is mounted at a second side, opposite to the first side, of the part, for coupling a fan inlet or outlet to the housing. A clamp mechanism is provided for pressing the fan aggregate towards the housing. One end of the clamp mechanism is attached to the housing and is at the same side of the fan aggregate as the elastic suspension, and another end of the clamp mechanism is attached to the fan aggregate and is at a position of the part or at a position of the motor, near a center of mass of the fan aggregate.

A working trolley with built-in dust suction system includes a dust suction system and a trolley. Through directly assembling the dust suction system with the trolley, useless structures in the dust suction system is eliminated, so that the dust suction system can be assembled with the trolley with a more simplified structure. Through directly assembling the dust suction system with the trolley, the trolley breaks the old and stereotyped way of using, and the trolley is no longer just a carrying tool of a vacuum cleaner, thereby greatly increasing the effectiveness of usage of the trolley. On the other hand, the present invention enables a dust storage bucket of the dust suction system to have a feature of being independently dismountable, so that an operator does not need to dismount other components when replacing the dust storage bucket, thereby facilitating operation for the operator.

As a result of the rotation of a fan (65) driven by a motor (40) inside a housing (2), dust-laden air that has been sucked in from a nozzle (92) passes through a filter device (95), flows as in (C1, C2), and is discharged from a discharge port (30) to the outside of the housing (2). Viewed in the direction of the axis (A1) of the motor (40): an air intake port (10) is located in front of the motor (40); a battery pack (100) is located behind the motor (40); and a handle (4) is located behind the motor (40). The air exhaust port (30) is located between the handle (4) and the battery pack (100) and is provided behind the center position of the battery pack (100) in the axis (A1) direction.