An assembly that includes a rotating shaft supported with respect to a stationary housing by at least one active magnetic bearing presenting a mean radial air gap and at least one auxiliary bearing having a bushing fixed to the housing and a sleeve fixed on the rotating shaft. The bushing and the sleeve have opposite surfaces that define a clearance (E2) which is less than the mean radial air gap (E1). The bushing and the sleeve each exhibit symmetry around a longitudinal axis of the shaft and have different profiles in a longitudinal cross-section including the longitudinal axis to optimize the contact pressure distribution when the rotating shaft lands on the auxiliary bearing.

An electrical connector providing a sealed electrical link between an inside environment subjected to corrosive gases or liquids under pressure and an outside environment of different pressure. The connector includes a connector body, conductor cables, a thermoplastic insulator, and a sealing element. The connector body is secured to a structure and includes insulating feed-throughs for receiving electrical contacts connecting an outside environment to an inside environment. The conductor cables, comprising an outer insulating layer made of a fusible thermoplastic material, are connected to said electrical contacts inside said inside environment. The thermoplastic insulator is secured to said connector body and surrounds the conductor cables. The thermoplastic insulator and cable outer insulating layers are made of a same type of fusible thermoplastic material making it possible, by localized fusion, to form a thermoplastic weld therebetween. The sealing element is mounted between the connector body and the thermoplastic insulator.

A compression system may include a compressor having first and second sides separated by a division wall, first and second shafts, and first and second radial bearings. The first and second shafts may be axially connected to each other at respective first ends via a rotor portion of an intermediate radial bearing. The rotor portion may include a plurality of laminations stacked between first and second plates fastened to each other. The first radial bearing may be disposed on a first side of the intermediate radial bearing and may be proximate a second end of the first shaft. The first radial bearing may be configured to support the first shaft. The second radial bearing may be disposed on a second side of the intermediate radial bearing and may be proximate a second end of the second shaft. The second radial bearing may be configured to support the second shaft.

A flow-conditioning system includes a pump, process tubing coupling the pump to a source of multiple component process fluid, and an in-line flow-mixing device positioned in the process tubing upstream of the pump. A system includes a well disposed below a body of water and providing a source of multiple component fluid, a pump disposed in and exposed to the water, process tubing coupling the pump to the well, and an in-line flow-mixing device positioned in the process tubing upstream of the pump.

The present disclosure relates to a stator of a magnetic levitation bearing, a magnetic levitation bearing, and a compressor. The stator of the magnetic levitation bearing includes a stator core (4), a stator coil (5) wound around the stator core (4), a housing (2) sleeved outside the stator core (4) and having a clearance fit or a transition fit with the stator core (4), and a potting component (3) filled between the housing (2) and the stator core (4).

A magnetic bearing apparatus capable of correcting inclination of a rotating element with a small magnetic attractive force and capable of stably supporting the rotating element is disclosed. The magnetic bearing apparatus includes: a non-magnetic ring made of non-magnetic material; and at least three axial magnetic poles arranged along a circumferential direction of the non-magnetic ring. Each axial magnetic pole has an arc-shaped coil and a coil housing that accommodates the coil therein. The at least three axial magnetic poles are fixed to the non-magnetic ring.

A thrust magnetic bearing includes a coil formed by winding a conductive wire, and a core that houses the coil. The core is provided with a refrigerant inlet and a refrigerant outlet. A refrigerant flow path connecting the refrigerant inlet and the refrigerant outlet is provided between the coil and the core. The refrigerant flow path is formed so that a refrigerant flowing from the refrigerant inlet to the refrigerant outlet mainly flows along the coil in a winding direction of the coil.

A routing support (3) for a cable (14) for a position sensor for a magnetic bearing module (1). The position sensor for said magnetic bearing module (1) includes an arrangement of coils (11) wound on spools and an insulation displacement contact (12). The routing support (3) includes a track for routing said cable (14) and openings (4) allowing the insertion of said cable (14) in the insulation displacement contact (12) through some of the openings (4) when the routing support (3) is positioned facing said position sensor for said magnetic bearing module (1). A magnetic bearing module (1) includes such a routing support (3). A method of producing such a magnetic bearing module (1).

A stator assembly for a magnetic bearing includes a core member formed of a ferromagnetic material and including an outer annular portion and a plurality of projections extending radially inwardly from the outer annular portion and spaced circumferentially about a centerline. A plurality of bobbins are formed of an electrically insulative material and include a first shell half disposed against a first axial end of a separate one of the projections and a second shell half disposed against a second axial end of the projection. The second shell half is coupled with the first shell half such that the one projection is enclosed within a cavity defined between the two shell halves. A plurality of windings each include at least one wire wound about a bobbin and electrically coupleable with a source of electric power such that each winding and the projection encircled by the winding provide a magnetic pole.

There is provided a permanent magnet electric motor that can be downsized in a rotation axis direction and can also suppress a leakage flux. The permanent magnet electric motor includes: a columnar rotor including a permanent magnet portion annularly disposed; a shaft disposed along a rotation axis of the rotor; a cylindrical stator core disposed on an outer circumferential side of the rotor; a main body including a shell integrally formed with the stator core; a bracket attached to one end side of the main body; and a bearing that rotatably supports the shaft. The bracket includes a bearing house portion that stores the bearing, and a non-magnetic portion that is connected to the bearing house portion. The bearing house portion is disposed on an inner diameter side relative to the permanent magnet portion as viewed from an axis direction of the rotation axis, and an edge portion of the bearing house portion on an outer diameter side is covered with the non-magnetic portion.