The disclosure relates to methods, systems and compositions for use in the harvesting of nectar from plants or their portions. More specifically, the disclosure relates to systems, compositions and methods for semi-continuously harvesting nectar from plants or their portions having extrafloral nectaries (EFN) with augmented nectar production.

The disclosure relates to methods, systems and compositions for use in the harvesting of nectar from plants or their portions. More specifically, the disclosure relates to systems, compositions and methods for semi-continuously harvesting nectar from plants or their portions having extrafloral nectaries (EFN) with augmented nectar production.

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 filter unit (10) for separation of particulate matter from particulate-laden liquid, the filter unit comprising: a chamber (12) defined by an upper axial end wall (14) and an opposing lower axial end wall (16) and a peripheral particle collection wall (18), the upper and lower axial end walls being spaced by the peripheral particle collection wall, the chamber being rotatable about an axis of rotation (30) so as to impart rotational motion to the liquid; an inlet (23) for delivering particulate-laden liquid into the chamber (12); an outlet (24) in the upper or lower axial end wall for discharging filtered liquid from the chamber; a flow path (22) from the inlet to the outlet; wherein the flow path includes a radial component from the inlet to the peripheral particle collection wall and an axial component along the peripheral particle collection wall.

A filter unit (10) for separation of particulate matter from particulate-laden liquid, the filter unit comprising: a chamber (12) defined by an upper axial end wall (14) and an opposing lower axial end wall (16) and a peripheral particle collection wall (18), the upper and lower axial end walls being spaced by the peripheral particle collection wall, the chamber being rotatable about an axis of rotation (30) so as to impart rotational motion to the liquid; an inlet (23) for delivering particulate-laden liquid into the chamber (12); an outlet (24) in the upper or lower axial end wall for discharging filtered liquid from the chamber; a flow path (22) from the inlet to the outlet; wherein the flow path includes a radial component from the inlet to the peripheral particle collection wall and an axial component along the peripheral particle collection wall.

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.

The disclosure relates to methods, systems and compositions for use in the harvesting of nectar from plants or their portions. More specifically, the disclosure relates to systems, compositions and methods for semi-continuously harvesting nectar from plants or their portions having extrafloral nectaries (EFN) with augmented nectar production.

The disclosure relates to methods, systems and compositions for use in the harvesting of nectar from plants or their portions. More specifically, the disclosure relates to systems, compositions and methods for semi-continuously harvesting nectar from plants or their portions having extrafloral nectaries (EFN) with augmented nectar production.