A cleaner includes a suction unit, a main body including a cyclone unit for separating dust from air suctioned through the suction unit, and a dust container that stores dust separated in the cyclone unit below the cyclone unit. A filter unit is disposed inside the cyclone unit for filtering the air, and a movable unit disposed inside the cyclone unit includes a cleaning part for cleaning the outer circumference of the filter unit. An operation unit disposed outside the main body moves the movable unit and the cleaning part to remove dust from the outer surface of the filter unit.

A cyclone sand separator kit, method, and separator, of which the kit includes a cyclone body having an inlet, a fluid outlet, and a solids outlet, the inlet being configured to receive a mixed fluid including a solid portion and a fluidic portion, the solids outlet being configured to receive the solid portion separated from the fluidic portion, and the fluid outlet being configured to receive the fluidic portion separated from the solids portion. The kit includes a plurality of cyclone inserts configured to be positioned in the cyclone body, at least partially between the inlet and the solids outlet and at least partially between the fluids outlet and the solids outlet. The cyclone inserts each define a vortical section configured to induce inertial separation of the mixed fluid, have different geometries including different inner diameters, lengths, angles, underflow outlet sizes, vortex finder placements, or a combination thereof.

A separator assembly including a first cyclone, a second cyclone, and a sealing plate. The second cyclone assembly includes a plurality of second cyclone separators arranged fluidly in parallel. At least a portion of the plurality of second cyclone separators is arranged in a ring of cyclones spaced radially from an axis and connected by wall portions. The sealing plate surrounds a portion of each of the second cyclone separators, configured such that each of the second cyclone separators extends through a respective opening defined in the sealing plate. A flow path is defined between the first cyclone separator to the inlets of the second cyclone separators, at least a portion of the flow path being bounded by at least a portion of an upper surface of the sealing plate and the wall portions.

A cyclone sand separator kit, method, and separator, of which the kit includes a cyclone body having an inlet, a fluid outlet, and a solids outlet, the inlet being configured to receive a mixed fluid including a solid portion and a fluidic portion, the solids outlet being configured to receive the solid portion separated from the fluidic portion, and the fluid outlet being configured to receive the fluidic portion separated from the solids portion. The kit includes a plurality of cyclone inserts configured to be positioned in the cyclone body, at least partially between the inlet and the solids outlet and at least partially between the fluids outlet and the solids outlet. The cyclone inserts each define a vortical section configured to induce inertial separation of the mixed fluid, have different geometries including different inner diameters, lengths, angles, underflow outlet sizes, vortex finder placements, or a combination thereof.

An integrated vortex separator (IVS) is disclosed. The IVS includes a housing in communication with a waste inlet via which a waste stream is drawn under suction into a waste tank. In a first stage, the waste stream is drawn into a centrifugal vortex flow to facilitate the removal of solid and liquid waste from the waste stream, leaving a primary airstream. Within the housing, a filter assembly includes outer and inner inverted cones with a conical cavity therebetween, the cavity serving as a second stage into which the vortex flow is redirected to remove additional liquid from the airstream. Radial vanes extending inward from the outer cone define portals between adjacent vanes, through which the redirected vortex flow is isolated from the original vortex flow. Exhaust ports in communication with the conical cavity allow the substantially moisture-free airstream to be drawn from the IVS via a vent line.

A vacuum cleaner includes a suctioning unit, a main body including a cyclone unit for separating dust from the air suctioned through the suctioning unit, a body forming a dust container for storing the dust separated by the cyclone unit, and a body cover for opening and closing the lower side of the body. A filter unit is arranged in the body for filtering air. An actuating unit is configured to move in the body along a space between the outside of the filter unit and the inner circumferential surface of the body.

Provided is a chiller and system that may be utilized in a supercritical fluid chromatography method, wherein a non-polar solvent may replace a portion or all of a polar solvent for the purpose of separating or extracting desired sample molecules from a combined sample/solvent stream. The system may reduce the amount of polar solvent necessary for chromatographic separation and/or extraction of desired samples. The system may incorporate a supercritical fluid chiller, a supercritical fluid pressure-equalizing vessel and a supercritical fluid cyclonic separator. The supercritical fluid chiller allows for efficient and consistent pumping of liquid-phase gases employing off-the-shelf HPLC pumps. The pressure equalizing vessel allows the use of off-the-shelf HPLC column cartridges. The system may further incorporate the use of one or more disposable cartridges containing silica gel or other suitable medium. The system may also utilize an open loop cooling circuit using fluids with a positive Joule-Thompson coefficient.

A surface cleaning apparatus comprises an air treatment member having an air treatment chamber. A moveable member is positioned in the air treatment chamber. A driving assembly is drivingly connected to the moveable member wherein the driving assembly is reconfigurable between a stored position and an operable position in which the driving assembly is operable to longitudinally translate the moveable member through at least a portion of the chamber.

Separators for separating a multi-phase composition include a separator casing defining a chamber and a permeate outlet, at least one hydrocyclone within the separator casing, and at least one ceramic membrane. Each hydrocyclone includes a hydrocyclone inlet, a tapered section downstream of the hydrocyclone inlet, an accepted outlet, and a reject outlet. The ceramic membrane may be disposed within the separator casing and downstream of the accepted outlet of the hydrocyclone or may be disposed within at least a portion of the tapered section of the hydrocyclone. The ceramic membrane includes a retentate side and a permeate side, where the permeate side is in fluid communication with the chamber. Systems and methods for separating a multi-phase composition into a lesser-density fluid, a greater-density fluid, and a medium-density fluid using the separators are also disclosed.

Separators for separating a multi-phase composition include a separator casing defining a chamber and a permeate outlet, at least one hydrocyclone within the separator casing, and at least one ceramic membrane. Each hydrocyclone includes a hydrocyclone inlet, a tapered section downstream of the hydrocyclone inlet, an accepted outlet, and a reject outlet. The ceramic membrane may be disposed within the separator casing and downstream of the accepted outlet of the hydrocyclone or may be disposed within at least a portion of the tapered section of the hydrocyclone. The ceramic membrane includes a retentate side and a permeate side, where the permeate side is in fluid communication with the chamber. Systems and methods for separating a multi-phase composition into a lesser-density fluid, a greater-density fluid, and a medium-density fluid using the separators are also disclosed.