A device for the processing and separation of biological fluids into components comprises a hollow centrifugal processing chamber (10) fitted with an inlet/outlet head (20) and preferably with an axially movable piston (18). The inlet/outlet head has two separate inlets/outlets, for instance an axial inlet (29) and a lateral outlet (40). The processing chamber (1) is fitted with an internal flow guide (30) enabling operation of the device in a continuous processing mode wherein biological fluid to be processed is continuously intaken by say the axial inlet (29) and at the same time processed components are continuously removed via say the lateral outlet (40). The continuous processing flow can be driven by an external peristaltic pump (59) and/or by axial displacement of a piston (18) in the chamber (10).

A device for the processing and separation of biological fluids into components comprises a hollow centrifugal processing chamber (10) fitted with an inlet/outlet head (20) and preferably with an axially movable piston (18). The inlet/outlet head has two separate inlets/outlets, for instance an axial inlet (29) and a lateral outlet (40). The processing chamber (1) is fitted with an internal flow guide (30) enabling operation of the device in a continuous processing mode wherein biological fluid to be processed is continuously intaken by say the axial inlet (29) and at the same time processed components are continuously removed via say the lateral outlet (40). The continuous processing flow can be driven by an external peristaltic pump (59) and/or by axial displacement of a piston (18) in the chamber (10).

A centrifuge for separating minerals by specific gravity is disclosed. The centrifuge rotates to circulate slurry across a collection region and to subject slurry in the collection region to centripetal forces that facilitate stratification within the collection region by the specific gravity of the constituent minerals of the slurry. Energy, such as acoustic energy, is coupled with the collection region and enhances the stratification by specific gravity within the collection region.

A centrifuge for separating minerals by specific gravity is disclosed. The centrifuge rotates to circulate slurry across a collection region and to subject slurry in the collection region to centripetal forces that facilitate stratification within the collection region by the specific gravity of the constituent minerals of the slurry. Energy, such as acoustic energy, is coupled with the collection region and enhances the stratification by specific gravity within the collection region.

A lower partition wall having a through hole vertically penetrates the lower partition wall center. A spindle is inserted into the through hole. The top surface side of the lower partition wall includes a convex portion, a groove, and a drain hole. The convex portion is concentrically disposed at the through hole periphery. The groove extends, from an outer peripheral side of the convex portion, toward the through hole on an inner peripheral side. The drain hole is outside the convex portion, vertically penetrating the lower partition wall. The separated oil circles a top surface of the lower partition wall. The oil flowing to an inner peripheral side of the lower partition wall is guided to the groove and flows into the through hole. The oil flowing to an outer peripheral side of the lower partition wall flows into the drain hole.

The present disclosure includes a centrifuge system for processing a massecuite composition. The centrifuge system may include a centrifuge having a vertical spindle, a housing, and a basket disposed within the housing. The basket may include a central hub coupled to the vertical spindle for rotation therewith, a cup coupled to the central hub or an end of the vertical spindle, and a loading cone positioned over the cup and coupled to the cup by a plurality of vanes extending outward from the cup to the loading cone. The loading cone may have a wide end open towards a bottom of the basket, and the plurality of vanes may be radially spaced apart. The centrifuge system may further include a feed pipe vertically disposed above the cup and having a feed outlet oriented towards the cup. The cup defining a cavity oriented in a direction away from the central hub.

The present disclosure includes a centrifuge system for processing a massecuite composition. The centrifuge system may include a centrifuge having a vertical spindle, a housing, and a basket disposed within the housing. The basket may include a central hub coupled to the vertical spindle for rotation therewith, a cup coupled to the central hub or an end of the vertical spindle, and a loading cone positioned over the cup and coupled to the cup by a plurality of vanes extending outward from the cup to the loading cone. The loading cone may have a wide end open towards a bottom of the basket, and the plurality of vanes may be radially spaced apart. The centrifuge system may further include a feed pipe vertically disposed above the cup and having a feed outlet oriented towards the cup. The cup defining a cavity oriented in a direction away from the central hub.

The disclosure relates to methods, systems and compositions for producing emulated honey. More specifically, the disclosure relates to systems, compositions and methods for semi-continuously producing emulated honey using pressure-driven fluidic platforms comprising a plurality of microfluidic and/or milifluidic devices containing fluidic unit operations operable to convert plant nectar to emulated honey.

The disclosure relates to methods, systems and compositions for producing emulated honey. More specifically, the disclosure relates to systems, compositions and methods for semi-continuously producing emulated honey using pressure-driven fluidic platforms comprising a plurality of microfluidic and/or milifluidic devices containing fluidic unit operations operable to convert plant nectar to emulated honey.

A centrifugal separator for cleaning a gas containing liquid impurities includes a stationary casing including a surrounding sidewall, a first end wall and a second end wall which enclose a space through which a gas flow is permitted. The space includes an upper separation chamber and a lower discharge chamber. The separator further includes an inlet extending through the stationary casing and permitting supply of the gas to be cleaned to the separation chamber, a rotating member including a stack of separation discs and being arranged to rotate around an axis of rotation, wherein the stack of separation discs is arranged in the separation chamber and a drive member for rotating the rotating member. The discharge chamber is arranged axially below the stack of separation discs such that clean gas and separated liquid impurities both enter said discharge chamber after being separated in said stack of separation discs, and further, the separator includes a gas outlet configured to permit discharge of cleaned gas from said stationary casing, wherein the gas outlet includes an outlet opening through the stationary casing and a portion extending from the outlet opening into the discharge chamber. Further, there is a drainage outlet arranged in said discharge chamber and configured to permit discharge of separated liquid impurities from said stationary casing.