A separation assembly comprises a housing and a bearing plate assembly. The housing contains a turbine assembly and a rotor portion and defines a fluid inlet and a fluid outlet. The bearing plate assembly is adjustably attachable to the housing and defines a drive jet that directs fluid from the fluid inlet to the turbine assembly. The bearing plate assembly is mountable to the housing in multiple different orientations such that the relative position of the fluid inlet of the housing and the drive jet of the bearing plate assembly is adjustable.

A separation assembly comprises a housing and a bearing plate assembly. The housing contains a turbine assembly and a rotor portion and defines a fluid inlet and a fluid outlet. The bearing plate assembly is adjustably attachable to the housing and defines a drive jet that directs fluid from the fluid inlet to the turbine assembly. The bearing plate assembly is mountable to the housing in multiple different orientations such that the relative position of the fluid inlet of the housing and the drive jet of the bearing plate assembly is adjustable.

A centrifuge has a mechanical drive coupled to a capsule rotatable simultaneously about mutually orthogonal X, Y, and Z axes. A stationary base has a first motor driving a centrally located hub in rotation about the Z axis. The hub has a pair of colinear arms and a pair of struts extending from the arms to support an outer ring. An inner ring is positioned concentric with the outer ring and a second motor is engaged with both the outer ring and inner ring so that it is enabled for rotating the inner ring relative to the outer ring. A third motor is engaged with both the inner ring and the capsule for rotating said capsule relative to the inner ring. The simultaneous rotation of the capsule about all three axes is therefore possible.

In a method of greasing a decanter centrifuge, each beating of the decanter centrifuge is located in a bearing housing and at least one bearing housing has a grease flow meter. The grease flow meter is connected to a control unit. The method includes generating a greasing operation when the operating time of the decanter centrifuge is equal to or exceeds a specific time interval between greasing operations. The greasing operation includes generating a start signal in the control unit, measuring an amount of grease injected into the bearing housing by using the flow meter, and generating a stop signal in the control unit when the amount of grease injected into the bearing housing is equal to or exceeds a specific amount of grease to be injected at each greasing operation.

In a method of greasing a decanter centrifuge, each beating of the decanter centrifuge is located in a bearing housing and at least one bearing housing has a grease flow meter. The grease flow meter is connected to a control unit. The method includes generating a greasing operation when the operating time of the decanter centrifuge is equal to or exceeds a specific time interval between greasing operations. The greasing operation includes generating a start signal in the control unit, measuring an amount of grease injected into the bearing housing by using the flow meter, and generating a stop signal in the control unit when the amount of grease injected into the bearing housing is equal to or exceeds a specific amount of grease to be injected at each greasing operation.

A skid (700) for use in separating biocomponents includes a housing (701) bounding a compartment (708), the compartment being partially bounding by a mounting platform (709); and a loading assembly (800) secured to the housing so as to communicate with the compartment. The loading assembly (800) includes an alignment plate (808) having a top surface with cavity (814) recessed therein, the cavity communicating with the compartment; a drive rotor (15) rotatably disposed below the alignment plate and at least partially encircling the cavity, the drive rotor including one or more magnets; a motor (169) coupled to the drive rotor for selectively rotating the drive rotor about the cavity; and a mount at least partially encircling the drive rotor and communicating with the compartment, the mount including a mounting plate having one or more mounting elements upstanding therefrom, the mount being movable between a raised position wherein the mounting plate is aligned with the alignment plate and a second lowered position wherein the mounting plate is disposed at an elevation lower than the alignment plate.

A skid (700) for use in separating biocomponents includes a housing (701) bounding a compartment (708), the compartment being partially bounding by a mounting platform (709); and a loading assembly (800) secured to the housing so as to communicate with the compartment. The loading assembly (800) includes an alignment plate (808) having a top surface with cavity (814) recessed therein, the cavity communicating with the compartment; a drive rotor (15) rotatably disposed below the alignment plate and at least partially encircling the cavity, the drive rotor including one or more magnets; a motor (169) coupled to the drive rotor for selectively rotating the drive rotor about the cavity; and a mount at least partially encircling the drive rotor and communicating with the compartment, the mount including a mounting plate having one or more mounting elements upstanding therefrom, the mount being movable between a raised position wherein the mounting plate is aligned with the alignment plate and a second lowered position wherein the mounting plate is disposed at an elevation lower than the alignment plate.

A protecting collar for a centrifugal separator is arranged to rotate with a rotatable part of the centrifugal separator and includes a cavity provided with an inner wall including a first inner peripheral surface portion and an inner abutment surface; a first and a second opening of the cavity, which first opening has a larger diameter than the second opening; an outer wall including an outer peripheral surface and an outer abutment surface. The protecting collar includes a lubricant barrier generating element arranged in the first inner peripheral surface portion, which lubricant barrier generating element is configured to prevent the lubricant to pass the lubricant barrier generating element during a rotational movement of the protecting collar. The lubricant barrier generating element is a helical groove formed in the first inner peripheral surface portion. A centrifugal separator includes the protecting collar.

A protecting collar for a centrifugal separator is arranged to rotate with a rotatable part of the centrifugal separator and includes a cavity provided with an inner wall including a first inner peripheral surface portion and an inner abutment surface; a first and a second opening of the cavity, which first opening has a larger diameter than the second opening; an outer wall including an outer peripheral surface and an outer abutment surface. The protecting collar includes a lubricant barrier generating element arranged in the first inner peripheral surface portion, which lubricant barrier generating element is configured to prevent the lubricant to pass the lubricant barrier generating element during a rotational movement of the protecting collar. The lubricant barrier generating element is a helical groove formed in the first inner peripheral surface portion. A centrifugal separator includes the protecting collar.

A centrifuge has a mechanical drive coupled to a capsule rotatable simultaneously about mutually orthogonal X, Y, and Z axes. A stationary base has a first motor driving a centrally located hub in rotation about the Z axis. The hub has a pair of colinear arms and a pair of struts extending from the arms to support an outer ring. An inner ring is positioned concentric with the outer ring and a second motor is engaged with both the outer ring and inner ring so that it is enabled for rotating the inner ring relative to the outer ring. A third motor is engaged with both the inner ring and the capsule for rotating said capsule relative to the inner ring. The simultaneous rotation of the capsule about all three axes is therefore possible.