A docking station for a robotic surface cleaning apparatus is provide. The docking station has a plurality of cyclones comprising an upper cyclone and a lower cyclone. The cyclones are arranged such that the dirt outlet of the upper cyclone is not obstructed by the dirt outlet of the lower cyclone.

An air treatment apparatus has a momentum separator positioned in an air flow path. The momentum separator has an upper wall, a lower wall, a sidewall extending between the upper and lower walls and a momentum separator air inlet. A momentum separator air inlet is provided in an inlet portion of the sidewall. The momentum separator air inlet faces an opposed portion of the sidewall that is opposed to the inlet portion of the sidewall and the inlet portion of the sidewall comprises a side screen.

A surface cleaning apparatus includes a cyclone having a plurality of tangential air inlets. Each tangential air inlet is formed of a sidewall and an end wall. The tangential air inlet has an inlet port which is positioned to face a wall of the cyclone chamber. The tangential air inlets have a flow straightener provided on a radial inner or outer side.

Provided is a microfluidic PDMS face mask, including a face mask body having a plurality of bores mounted on a surface thereof, a microfluidic block array including a plurality of microfluidic blocks being arranged in arrays and received in the bores, each of the microfluidic block includes a microfluidic module for allowing a fluid to flow therethrough, thereby capturing microparticles, and a strap having one end attached to a left side of the face mask body and the other end attached to a right side of the face mask body for adhering the face mask body to the face of a user.

A hand vacuum cleaner has an upstream air treatment stage having an upstream air treatment member and a longitudinal axis extending between the front and rear ends of the downstream air treatment stage, and a downstream air treatment stage a downstream air treatment member and a downstream dirt collection chamber that is exterior to the downstream air treatment member. The downstream air treatment member is positioned rearward of the upstream air treatment member. The downstream dirt collection chamber extends forward of the downstream air treatment member to a location that is forward of the rear end of the upstream air treatment stage.

A surface cleaning apparatus comprising a first cyclonic cleaning stage having a first cyclone chamber and a first dirt collection chamber external to the first cyclone chamber. The first cyclone chamber has a cyclone first end, an opposed cyclone second end, a cyclone sidewall extending between the cyclone first end and the cyclone second end, a cyclone air inlet, a cyclone air outlet, a cyclone dirt outlet in communication with the first dirt collection chamber and a cyclone longitudinal axis extending from the cyclone first end to the cyclone second end. The dirt outlet comprises a plurality of apertures.

An air intake separator system includes a plurality of vanes adapted to remove fluid or precipitation from an air stream, wherein the vanes are operably coupled to tubular rods with an interference fit. Applying an elevated temperature heat transfer fluid to the plurality of vanes removes fluid or precipitation from an air stream in order to prevent ice formation. Likewise, applying a lower temperature heat transfer fluid can cool the vanes.

Methods of separating a multiphase mixture are provided. The multiphase flow can include petrochemicals. The multiphase flow is flowed through a vane assembly having a plurality of curved passages. The multiphase mixture is gradually decelerated such that it collides with surfaces of the vane assembly at relatively oblique angles and at lower relative speeds. Such a configuration can reduce droplet breakup which, in turn, can preserve larger droplet sizes that are more likely to settle to a liquid bed below the inlet diverter due to gravity.

This invention relates to the separation of particulate contaminants from a fluid. In one embodiment of the invention, two sand separators placed in series may be used to separate sand from liquid or gaseous natural gas. This invention has some of its applications in the oil gas industry, particularly for use in separating sand from gas produced by natural gas wells that have been opened by hydraulic fracturing.

The present invention provides a fluid inlet device (1) for a separator, comprising a lower part (2) and an upper part (3), wherein the lower part (2) comprises an inner wall surface (4) having a horizontal cross-section comprising a circular arc, a top section (5) comprising a fluid outlet (6), a bottom section (7) comprising a liquid outlet (8), and a tangential fluid inlet (9) for introduction of a fluid flow to the inner wall surface (4); the upper part (3) comprises multiple guiding vanes (10) arranged to guide a fluid flow, entering the upper part through the fluid outlet (6), in a horizontal direction away from the fluid outlet.