A cleaning system and method of cleaning filters that removes the ash in the plugged regions is disclosed. The filter is subjected to vibrations, which serve to loosen trapped and packed retentate from the filter. The loosened retentate is then captured by a collection bin. The cleaning system can be integral with the intended application, such as within an automobile. In another embodiment, the cleaning system is a separate cleaning station, where the filter is removing from its intended application, cleaned, and then reinstalled.

The present invention relates to an appliance comprising, a regenerative filter for filtering a fluid flow, having at least one filter, a filter regenerator for regenerating the regenerative filter, a turbine for driving the filter regenerator, the turbine being driven by the fluid flow passing through the appliance during its use.

A regenerative filter comprising at least one filter having a plurality of layers of filter material, the filter having a filtering configuration where the plurality of layers of filter material are held together so that they are fixed relative to each other, and a regeneration configuration where the layers of filter material are held together at at least one point, such that one of the plurality of layers of filter material can be spaced from the other layers for regeneration, the filter being movable from a filtration zone, where the first filter is in its filtering configuration, to a regeneration zone which is spaced from the filtration zone and where the first filter is in its regeneration configuration, and a filter regenerator arranged to move at least a portion of at least one layer of filter material when the filter is housed in the regeneration zone.

The present invention relates to a surface cleaning apparatus comprising a regenerative filter having at least one filter, the at least one filter comprising a plurality of layers of filter material, the filter having a first filtering configuration where the plurality of layers are held together such that air to be cleaned can pass through the plurality of layers of filter media during use of the surface treating apparatus, and a second regeneration configuration wherein at least a portion of one of the plurality of layers of filter material is spaced from the remainder of the layers of filter material for regeneration, and a filter regenerator for regenerating the filter material.

A method for removing residual filter cakes that remain adhered to a filter after typical particulate removal methodologies have been employed, such as pulse-jet filter element cleaning, for all cleanable filters used for air pollution control, dust control, or powder control.

The invention relates to a device for coating substrates in a process chamber (8) of a reactor housing (1), having a gas inlet member (11) for introducing process gases into the process chamber (8), having a gas outlet member (10) for discharging an exhaust gas stream from the process chamber (8) into a particle filter (4), which is disposed in a particle separator housing (3) and has a porous filter medium (16) for out-filtering particles from the exhaust gas stream, which form during a reaction of the process gases. In order to improve the filtering performance of a particle filter at a CVD or PVD device and to specify a suitable particle filter for this intended purpose, the invention suggests that the pore size and the surface quality of the filter medium (16) are selected in such a manner that the particles located in the exhaust gas stream adhere to the surface of the filter medium (16), however do not penetrate the filter medium (16), and the particles grow to conglomerates outside of the filter medium (16), and a mass acceleration device is provided for cleaning the particle filter (4) by mechanically removing the conglomerates.

A metal work box includes a base having a horizontal planar member having an upper surface and a lower surface. The metal work box also includes a plurality of side walls secured to and extending upwardly from the base. The plurality of side walls include a front first side wall formed along a front first edge of the base, a back second side wall formed along a rear second edge of the base, a left third side wall formed along a left side third edge of the base, and right fourth side wall formed along a right side fourth edge of the base. A door is formed along the front first side wall. The door includes a door panel having a free edge and a hinged edge, the hinged edge being pivotally secured to a front hinge side wall portion of the front first side wall so as to enable easy access to contents. The front first side wall also includes a latch extending between a front latch side wall portion of the front first side wall and the free edge of the door panel to allow for selective latching of the door panel to the front latch side wall portion to keep the door securely closed.

A dust collector for use with a power tool comprises a housing, a telescoping suction pipe coupled to the housing, a suction fan positioned in the housing and operable to generate a vacuum in the suction pipe, a dust container coupled to the housing and positioned upstream of the fan, a filter at least partially arranged in the dust container, and a filter cleaning mechanism. The filter cleaning mechanism includes an anvil, a striker moveable between a first striker position, in which the striker is spaced from the anvil, and a second striker position, in which the striker is in contact with the anvil. The filter cleaning mechanism further includes an actuator moveable between a first actuator position and a second actuator position, in which the actuator is moved closer to the anvil than in the first position, and a first spring biasing the striker toward the anvil.

A filtration assembly (100) for a vacuum cleaner includes a filtration member (1) for filtering an impurity, in which an outer circumferential wall of the filtration member (1) is provided with a fixing frame (11) adapted to be fixed in the vacuum cleaner; and an ash tapping part (2) which includes a rack (21), a moving member (22), a gear (23) and a tapping member (24). Two ends of the rack (21) are fixed to the fixing frame (11), the moving member (22) is movably disposed to the rack (21), the gear (23) is disposed to the moving member (22) and meshes with the rack (21), the tapping member (24) is disposed to the gear (23) through a connecting shaft (241) so as to be driven to rotate by the gear (23), and the tapping member (24) is configured to tap the filtration member (1) during rotation to vibrate the filtration member (1).

A dust removal device includes: an upper cover, a base, a support body, and a dust collector. The support body couples with the upper cover and the base. The dust collector includes: a first connecting member, a second connecting member, and a dust collecting body. The dust collecting body is coupled with the first connecting member and the second connecting member and has a folded structure. When an external force enables a shape of the first dust collecting body to be changed, a distance between the first connecting member and the second connecting member is also changed. In a cleaning mode, the dust collecting body is stretched and compressed in a reciprocating manner by using a structure of the dust collecting body.