A solids separation apparatus (SSA) for removing solids concentrate from a continuous fluid stream. The solids separation apparatus includes a tower. The SSA includes a transducer operably engaged with a first end of the tower and configured to generate a standing sonic wave inside of the tower. The SSA also includes a reflector operably engaged with an opposing second of the tower and configured to reflect the standing sonic wave towards the transducer. The SSA also includes at least one set of ports defined in an interior wall of at least one solids removal stage of the tower. The at least one set of ports is positioned at anti-nodes of the standing sonic wave to recover solids concentrate from a fluid stream flowing through the tower. The transducer and the reflector of the SSA are linearly moveable relative to the tower to linearly move the standing sonic wave.

A solids separation apparatus (SSA) for removing solids concentrate from a continuous fluid stream. The solids separation apparatus includes a tower. The SSA includes a transducer operably engaged with a first end of the tower and configured to generate a standing sonic wave inside of the tower. The SSA also includes a reflector operably engaged with an opposing second of the tower and configured to reflect the standing sonic wave towards the transducer. The SSA also includes at least one set of ports defined in an interior wall of at least one solids removal stage of the tower. The at least one set of ports is positioned at anti-nodes of the standing sonic wave to recover solids concentrate from a fluid stream flowing through the tower. The transducer and the reflector of the SSA are linearly moveable relative to the tower to linearly move the standing sonic wave.

An apparatus and method to segregate particles suspended in a fluid with an obstacle field in the flow path of the fluid. The particles may be dispersed after an interaction with obstacles in the obstacle field. The obstacle-particle interactions may result in an asymmetrical particle shift or bump in which the particles are differentially dispersed relative to the obstacle and the fluid flow. Individual obstacles having properties that are asymmetrical are arranged creating asymmetrical gaps between adjacent pairs of obstacles to separate particles flowing through the device.

An apparatus and method to segregate particles suspended in a fluid with an obstacle field in the flow path of the fluid. The particles may be dispersed after an interaction with obstacles in the obstacle field. The obstacle-particle interactions may result in an asymmetrical particle shift or bump in which the particles are differentially dispersed relative to the obstacle and the fluid flow. Individual obstacles having properties that are asymmetrical are arranged creating asymmetrical gaps between adjacent pairs of obstacles to separate particles flowing through the device.

A method for separating biological entities in a fluid sample, which contains small, medium, and large biological entities, includes the steps introducing the fluid sample into a first microfluidic device as two streams along two sidewalls thereof; applying a first power to the first microfluidic device to exert a first acoustic radiation pressure to produce a first output fluid having a higher relative fraction of the large biological entities than the fluid sample and a second output fluid having a lower relative fraction of the large biological entities than the fluid sample; introducing the second output fluid into a second microfluidic device as two streams along two sidewalls thereof; and applying a second power, which is higher than the first power, to the second microfluidic device to exert a second acoustic radiation pressure to produce a third output fluid having a higher relative fraction of the medium biological entities than the fluid sample.

A method for separating biological entities in a fluid sample, which contains small, medium, and large biological entities, includes the steps introducing the fluid sample into a first microfluidic device as two streams along two sidewalls thereof; applying a first power to the first microfluidic device to exert a first acoustic radiation pressure to produce a first output fluid having a higher relative fraction of the large biological entities than the fluid sample and a second output fluid having a lower relative fraction of the large biological entities than the fluid sample; introducing the second output fluid into a second microfluidic device as two streams along two sidewalls thereof; and applying a second power, which is higher than the first power, to the second microfluidic device to exert a second acoustic radiation pressure to produce a third output fluid having a higher relative fraction of the medium biological entities than the fluid sample.

An apparatus and method disperse particles suspended in a fluid with an obstacle field in the flow path of the fluid. The particles may be dispersed after an interaction with obstacles in the obstacle field. The obstacle-particle interactions may result in an asymmetrical particle shift in which the particles are dispersed in an asymmetrical manner relative to the obstacle and the fluid flow. Obstacles are arranged to separate particles flowing through the device based on individual obstacles having properties that are asymmetrical and are oriented and aligned for the separation.

An apparatus and method disperse particles suspended in a fluid with an obstacle field in the flow path of the fluid. The particles may be dispersed after an interaction with obstacles in the obstacle field. The obstacle-particle interactions may result in an asymmetrical particle shift in which the particles are dispersed in an asymmetrical manner relative to the obstacle and the fluid flow. Obstacles are arranged to separate particles flowing through the device based on individual obstacles having properties that are asymmetrical and are oriented and aligned for the separation.

A feedstock processing system extracts a product from a solid using a CTSE system comprising a plurality of continuous stirred tank extraction stages arranged in fluid communication with each other in series such that effluent from one stage flows to a next stage in the series. One of the stages has an inlet to allow a measured amount of liquid solvent and the solid to be introduced to the continuous stirred tank extraction stage. The stage mixes the solid with the introduced solvent to form a homogeneous slurry to enable the product associated with the solid to be extracted with the solvent. A solid-liquid separator is arranged in fluid communication with the continuous stirred tank extraction stages, and receives an effluent from one of the stages and separates the liquid solvent containing the product from the solid to form a product-containing liquid and a product-depleted solid.

A feedstock processing system extracts a product from a solid using a CTSE system comprising a plurality of continuous stirred tank extraction stages arranged in fluid communication with each other in series such that effluent from one stage flows to a next stage in the series. One of the stages has an inlet to allow a measured amount of liquid solvent and the solid to be introduced to the continuous stirred tank extraction stage. The stage mixes the solid with the introduced solvent to form a homogeneous slurry to enable the product associated with the solid to be extracted with the solvent. A solid-liquid separator is arranged in fluid communication with the continuous stirred tank extraction stages, and receives an effluent from one of the stages and separates the liquid solvent containing the product from the solid to form a product-containing liquid and a product-depleted solid.