A filtration unit for separating at least one analyte from a fluid sample. The filtration unit includes: an inlet configured to receive the fluid sample and an outlet configured to receive the at least one analyte; a fluid pathway providing fluid communication between the inlet and the outlet, where the fluid pathway has a longitudinal axis along which the fluid sample flows, in use; a filter located in the fluid pathway, where the filter includes at least one surface configured to allow the passage of the at least one analyte and the at least one surface is substantially transverse to the longitudinal axis of the fluid pathway; and an impeller located adjacent to the filter, where the impeller is configured to generate tangential fluid flow in the vicinity of the filter and wherein the impeller includes a rotatable shaft coupled to at least one blade having a rounded leading edge.

A filtration unit for separating at least one analyte from a fluid sample. The filtration unit includes: an inlet configured to receive the fluid sample and an outlet configured to receive the at least one analyte; a fluid pathway providing fluid communication between the inlet and the outlet, where the fluid pathway has a longitudinal axis along which the fluid sample flows, in use; a filter located in the fluid pathway, where the filter includes at least one surface configured to allow the passage of the at least one analyte and the at least one surface is substantially transverse to the longitudinal axis of the fluid pathway; and an impeller located adjacent to the filter, where the impeller is configured to generate tangential fluid flow in the vicinity of the filter and wherein the impeller includes a rotatable shaft coupled to at least one blade having a rounded leading edge.

A filtering and concentrating apparatus having a stirring function for small ternary precursor particles, comprising a barrel (100). One end of the barrel (100) is provided with a first closure (101), and the other end of the barrel (100) is provided with a second closure (102). The barrel (100) or the first closure (101) or the second closure (102) is provided with a feed port (103). One or more discharge pipes (200) are provided on the inner wall of the barrel (100). Microporous filtering mediums (300) communicated with the interior of the discharge pipe (200) are provided on the discharge pipe (200). An end portion of the discharge pipe (200) is communicated with the exterior of the barrel (100). A stirring means (800) is provided inside the barrel (100).

A vertical separator for the treatment of slurry includes a screen device with a vertical axis provided with a screen, a feeding device provided with a pump to feed the slurry to a screen device, a discharge device for the liquid part of the slurry, and a discharge device for the solid particles of the slurry. The screen device houses a counter-pressing device which is designed to generate a force which partially counters the pushing action exerted by the pump upon the slurry.

A vertical separator for the treatment of slurry includes a screen device with a vertical axis provided with a screen, a feeding device provided with a pump to feed the slurry to a screen device, a discharge device for the liquid part of the slurry, and a discharge device for the solid particles of the slurry. The screen device houses a counter-pressing device which is designed to generate a force which partially counters the pushing action exerted by the pump upon the slurry.

Screen designs and screens for a mechanical separation device are disclosed for separating solids from liquids in a process stream. A screen may have a plurality of openings, which are conical shaped, having a diameter of about 1.0 mm to about 1.4 mm in size that are formed on a stainless steel sheet.

Screen designs and screens for a mechanical separation device are disclosed for separating solids from liquids in a process stream. A screen may have a plurality of openings, which are conical shaped, having a diameter of about 1.0 mm to about 1.4 mm in size that are formed on a stainless steel sheet.

This invention relates generally to a filtration process and apparatus for separating valuable or harmful process liquids from mixtures or slurries that contain such liquids and solid particles. In particular, the invention relates to a filtration process for separating Process Liquid from a feed slurry that comprises a mixture of the Process Liquid and solid particles, the process employing a Sweep Liquid that is less dense than the Process Liquid.

This invention relates generally to a filtration process and apparatus for separating valuable or harmful process liquids from mixtures or slurries that contain such liquids and solid particles. In particular, the invention relates to a filtration process for separating Process Liquid from a feed slurry that comprises a mixture of the Process Liquid and solid particles, the process employing a Sweep Liquid that is less dense than the Process Liquid.

The present disclosure relates to a separation device to separate contaminants from contaminated water. It comprises a container to receive the contaminated water. The container further comprises a contaminated water inlet, a filter, a presser for compressing and/or dewatering contaminants separated from the contaminated water, and a contaminant outlet. The container further comprises a gas inlet for generating gas bubbles into the contaminated water to further separate contaminants from the contaminated water. The present disclosure relates to a use of such a separation device and a method of separating contaminants from contaminated water.